This is a licensed adaptation of the classic Serge DTG/DUSG

The Serge VCS module released in conjunction with from bananalogue.com is an extremely versatile control voltage generator and audio source. In the early 1970s, Serge Tcherepnin developed the Positive Slew and Negative Slew modules for the original Serge synthesizer. In time these merged into the classic Dual Universal Slope Generator. The Bananalogue VCS and CGS75 are an adaptation of Serge's original circuit with a few new features.

The VCS is a unity gain voltage follower. The rising and falling slopes are independently and jointly voltage controllable over a wide range.

VC Transient Envelope Generator

A pulse at the trigger input will start the envelope, or a gate input will sustain the level and the envelope will fall when the gate goes low. Rise and fall are independently and jointly voltage controllable, with variable linear and exponential wave shapes.

VC Portamento

Voltage is slewed according to the rise and fall times.

VC LFO

When the cycle switch is thrown, the trigger input is connected internally to the end trigger output, creating a VC clock with variable waveform and independent rise and fall times.

VC Oscillator

While not as wide ranged, or accurate as a dedicated oscillator module, the VCS is still an excellent audio source. The Exp CV input is scaled approximately to the 1v/oct standard. The Output wave can be swept from triangle to saw with linear and non-linear waveforms. End Out also produces a pulse waveform.

VC Non-Linear Audio Processor (Low-Pass Gate)

If an audio rate signal is slewed, the module responds like a VCF, and a rough VCA. The signal is low-pass filtered down to silence, similar to a low-pass gate.

Envelope Follower

Positive and negative peak detection envelope follower.

VC Pulse Delay

Trigger input starts the envelope and a trigger will be produced again at the End Out when the envelope completes its cycle.

Sub-Harmonic Generator

If a series of triggers are applied to the VCS faster than the total rise and fall times, the module will divide the incoming signal by a whole number. In the audio range the output will be the sub-harmonic series.

(Description taken from the former Bananalogue site)

A little on how it works.

Bipolar out gives an inverted signal.

AC out gives the non-inverted signal, but centered around 0V.

The schematic for the Euro version is different in the area of the switches SWF and SWR, though functionality remains the same.

For those interested in the theory of operation, I recommend Tim Stinchcombe's page on the subject.

The schematic of the VCS. Several suggested component changes are indicated on the diagram.

Construction

The component overlay for the VCS. Click here for an enlarged, printable version. Print at 300dpi for a correct scale printout.

Notes: The CGS75 version of the PCB includes a voltage processor. This allows a signal to be swept from _1 gain to -1 gain (i.e. inverted). It can be used with the "both" input or signal input, or it can be ignored and the associated parts left of the PCB.

It is a good idea to match the transistors of the same type in the core with each other. At least use transistors from the same batch.

On the first run of these PCBs (REV0.0 red boards) the specified 220k resistor connected to the emitters of the four transistors should be 8k2. On the VER1.0 boards, the 22k resistor in this location should be 8k2.

Before you start assembly, check the board for etching faults. Look for any shorts between tracks, or open circuits due to over etching. Take this opportunity to sand the edges of the board if needed, removing any splinters or rough edges. (With the boards supplied by me, the edges are already milled, and etching faults are very rare.)

When you are happy with the printed circuit board, construction can proceed as normal, starting with the resistors first, followed by the IC socket if used, then moving onto the taller components.

Take particular care with the orientation of the polarized components such as electrolytics, diodes, transistors and ICs.

When inserting ICs into sockets, take care not to accidentally bend any of the pins under the chip. Also, make sure the notch on the chip is aligned with the notch marked on the PCB overlay.

The holes without pads near the input and output pads are to allow a wire to be fed up from the bottom side, looped over and then soldered to the pad. The slack is then pulled back through the hole, creating an anchor that holds the wire by its insulation, reducing the chance of wire breakage. It is also helpful for a system such as Serge, where wires are traditionally connected from the solder side of the PCB.

A problem in the genuine Serge is that cycle locks up at various frequencies due to a charge inbalance in the trigger circuit. If you experience this problem, it can be solved by changing the 10n capacitor to 1n. These changes are marked on the circuit diagram.

ac out	ac out jack
bo	bi-polar output jack
out	out jack
trig in	trigger in jack
cy sw	(x 2) cycle switch. Switch connects these together for cycle mode
end	end out jack
rrw	rise rate wiper
	CW end of rise rate pot connects to +ve
	CCW end of rise rate pot connects to 0V
frw	fall rate wiper
	CW end of fall rate pot connects to +ve
	CCW end of fall rate pot connects to 0V
exp	exponential cv jack
rise cv	rise cv jack
both cv	both cv jack
in	input jack
swf	(x 2) fall switch. Switch connects these together for exp. response.
swr	(x 2) rise switch, Switch connects these together for exp. response.
rw	rise pot wiper
rccw	rise pot counter-clockwise
rcw	rise pot clockwise
fcw	fall pot clockwise
fccw	fall pot counter-clockwise
fw	fall pot wiper
fcv	fall cv jack
pout	processor output jack
pccw	processor pot ccw
pcw	processor pot cw
pr1	processor input
pr2	processor pot wiper

Note: You may need to reverse the connections to some of the pots to get them to work in the direction you wish.

Setting up