CGS Bi-N-Tic voltage controlled filter/oscillator (previous version)

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CGS57 the CGS Bi-N-Tic voltage controlled filter/oscillator is a strange mixture of a VCO and a switched capacitor filter based on the filter presented by Jan Hall in Electronotes. If you are after something different, this fits the bill. After all, how many filters have a sync input?

The module should work on +/-12 volts if the 20k resistor connected to pin 3 of the LM311 is reduced to 14k. (untested).

A little on how it works

Bi-N-Tic voltage controlled filter/oscillator schematic. Click through for a larger version.
Standard power rail decoupling

This filter is based on the original idea by Jan Hall, as presented in Electronotes EN92 P14-15.

A VCO drives a pair of analog switches, switching two banks of eight 0.047uF (47nF) capacitors across op-amps (effectively creating multiple integrators), and this a multi-bandpass or comb filter is created at f0, f1, f2 etc.. The overall filter configuration itself should be easily recognized. Two controls are provided within the structure of the filter - damping and bandwidth. Not all combinations of these two are actually valid, some resulting in silence, but none the less, quite an array of variations is possible.

The VCO section has been re-vamped, based on the well known Electronotes ENS-76 VCO Option 1[note 1] as used in the ASM-1, etc. This core was an obvious choice due to the amount of information, lists of suitable substitutes and so on that are available on the web. In this case, a cut-down version is used as its purpose was simply to drive the analog switches. The VCO is connected via a signal processor to the input of a 4024 binary counter. The first three divisions are used to drive the address lines of the 4051 analog switches.

While not shown on the circuit diagram, the remaining divider outputs are also available. They are not buffered, and are thus not suitable for connection to panel jacks, but they can be wired to a rotary switch, followed by a level pot, and fed back into the input of the filter itself, thus giving the filter an excitation signal that is perfectly in sync with its operating frequency. When configured like this, the filter becomes a very unusual oscillator giving quite complex, waveforms or even simple waveform sequences (ringing bursts).


The component overlay for the REV1.3 PCB. Click through for an enlarged, printable version. Print at 300dpi. Note that this is a later board than shown in the wiring diagrams, although the connection points retain the same names.
The component overlay and basic wiring for the Bi-N-Tic Filter. All pots are viewed from the rear.
• Tune 100k Lin (fine tune)
• Freq 100k Lin (coarse tune)
• Damping 50k Lin (resonance)
• Bandwidth 100k Lin dual
It is of course possible to add level pots to the CV and signal inputs. There are pads supplied for an optional second signal input and second output. Additional CV inputs may be added through additional resistors to the CVSN (Control Voltage Summing Node) pad.
The optional wiring for the Bi-N-Tic Filter. All pots are viewed from the rear. The lower divisor outputs of the 4024 are selected via positions 2 to 5 of a rotary switch. Position 1 is the optional Input 2 jack. The output of the switch is fed via a level pot to the second signal input on the PCB. Positions 2 to 5 of the rotary switch now provide four signals, one octave apart, to "excite" the filter when it is adjusted to be near resonant, or if the filter is backed off, four octaves of square wave VCO output.

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.

While LF356 op-amps have been specified, any single op-amp should be suitable. TL071, TL081 etc. certainly work in the circuit.

Parts list

This is a guide only. Parts needed will vary with individual constructor's needs.

Part Quantity
18pF 1
100pF 3
2n2 styrene 1
47n 16
100n 8
10uF 25V 2
Resistors (1% metal film)
330R 1
680R 1
1k PT146 tempco 1
1k 6
2k2 2
3k3 1
8k2 2
10k 13
15k 2
20k 1
47k 1
56k 1
100k 13
150k 1
1M 1
10k 25 turn trim 1
100k 25 turn trim 1
1N4148 1
2N4856 or sim 1
BC547 4
BC557 1
LF356 or TL071 4
TL072 1
CA3140 1
LM311 1
LM394 or sim 1
4024 1
4051 2
Ferrite bead (or 10R resistor) 2
0.156 4 pin connector 1


  • The MPF102 is reportedly causing some oscillators to fail or be very weak. As such, it may be best to avoid using them as the FET. I originally used them in my VCOs because it was all I could get locally. I have not tried them in the Bi-N-Tic, instead assuming they would suffice, as they had in the VCOs. These days I use 2N4091.
  • Some people find that "near enough is good enough" for filter tuning. In this case, the PT146 tempco resistor can be replaced with an ordinary 1k resistor, and the LM394 replaced with a pair of NPN transistors such as BC547 or 2N3904 (preferably matched).
  • Dual transistors. Substitutes can be made for the LM394. Other dual transistors that should work are 2SC3381, 2SC1583, MAT02, SSM2210. Some will be of a physically different configuration.
  • Alternate FETs include 2N4091, 2N4391, PN4091 2N4391 PN4391 PN4856, MPF108.
  • The version 1.1 PCB has an error at the 1N4148 diode. Connect the cathode to the base of the nearby BC547 instead of the cluster of 4 pads.
  • PCB 2" x 6" with four 3mm mounting holes 0.15" in from the edges.


Readers are permitted to construct these circuits for their own personal use only. Ken Stone retains all rights to his work.

See also



  1. ^ ENS-76 VCO Option 1 by Hutchins, Bernie,Terry Mikulic, Electronotes No. 75, March 1977, pp. 6-9. and fig. 4-9, p. 94

External links