Ninni's DIY VCA shootout
A good VCA is important for the sound quality in an
analog synthesizer. There are a number of special purpose VCA
circuits that satisfy these needs. The problem with most of them is
that they are either expensive, hard to find, out of production or
all of the above. I wanted to find out which is the best VCA that you
can build with cheap, easy to get parts. To test the circuits I built
prototypes on Veroboard. The circuits were adapted, if necessary, to
give unity gain at 10 V CV and accept an input signal of 10 V peak to
peak with some headroom.
The measurements were done years ago
with an Audio
Precision System Two. Noise level was plotted at different
frequecies by sweeping a bandpass filter in the AP. This was done
with the VCA control voltage at both 0 and 10 volt and the input
grounded. Noise was also measured with the signal generator in the AP
swept together with the bandpass filter. This shows the signal
bleedthrough at different frequencies. In this measurement the signal
level from the AP was 10 volts peak to peak. Of course the control
voltage in this case was 0 V.
Signal to noise was also measured
without the bandpass filter but with an A-weighting filter. This was
done with no input signal and with three different input signal
frequencies (1, 2 and 10 kHz). Without signal, measurements were made
with the VCA closed (0 V CV) and opened (10 V CV). To check the
distortion at different signal levels, the singal amplitude was swept
between -60 and +20 dBv and the THD+noise was plotted. This also
showed the lowest possible distortion and the headroom. The latter
was considered to be the level where the distortion exceeded one
percent. If this level was lower than 10 V p-p (10,968 dBv) the
circuit generally was changed and new measurements were made.
Frequency response was measured by sweeping the generator in the
AP. All circuits had practically flat response throughout the audible
range.
Distortion was also measured by sweeping the frequency at
two different input levels (0 dBv and 11 dBv). It turned out that the
distortion did not change noticeably with frequency. Therefore the
plots are not included.
Measurement summary
|
VCA type |
CV bleed- |
Lowest distortion |
Head- |
SNR @ 10V CV, no signal |
SNR @ 0V CV, |
Signal |
Signal |
Signal |
|
20 mV |
0,09% |
8 dBr |
81 dBr A |
117 dBr A |
97 dBr A |
91 dBr A |
83 dBr A |
|
|
20 mV |
0,10% |
8 dBr |
82 dBr A |
109 dBr A |
98 dBr A |
93 dBr A |
85 dBr A |
|
|
40 mV |
0,12% |
7 dBr |
83 dBr A |
110 dBr A |
105 dBr A |
101 dBr A |
86 dBr A |
|
|
20 mV |
0,65% |
-12 dBr |
78 dBr A |
106 dBr A |
76 dBr A |
71 dBr A |
59 dBr A |
|
|
15 mV |
0,06% |
5 dBr |
83 dBr A |
109 dBr A |
94 dBr A |
88 dBr A |
74 dBr A |
|
|
5 mV |
0,15% |
6 dBr |
82 dBr A |
107 dBr A |
86 dBr A |
80 dBr A |
63 dBr A |
|
|
6 mV |
0,15% |
5 dBr |
77 dBr A |
117 dBr A |
83 dBr A |
76 dBr A |
65 dBr A |
|
|
2 mV |
0,13% |
5 dBr |
81 dBr A |
110 dBr A |
85 dBr A |
77 dBr A |
67 dBr A |
|
|
2 mV |
0,10% |
5 dBr |
78 dBr A |
110 dBr A |
86 dBr A |
78 dBr A |
66 dBr A |
|
|
5 mV |
0,15% |
5 dBr |
83 dBr A |
107 dBr A |
88 dBr A |
80 dBr A |
64 dBr A |
|
|
500 mV |
0,07% |
0 dBr |
93 dBr A |
103 dBr A |
78 dBr A |
79 dBr A |
78 dBr A |
|
|
200 mV |
0,17% |
-4 dBr |
83 dBr A |
95 dBr A |
95 dBr A |
93 dBr A |
81 dBr A |
|
|
220 mV |
0,18% |
2 dBr |
80 dBr A |
97 dBr A |
95 dBr A |
94 dBr A |
87 dBr A |