5U Oakley Modular Series Voltage Controlled Oscillator User Manual
Contents
1. Replaced the now deleted CA3080 from the sine shaping circuitry The new board simply uses one half of an LM13700 device Easy to fit to the Oakley CV gate buss using an optional three way header fitted to the new socket board All PCBs are now RoHS compliant Issue 5 Boards had the following features added Mechanical changes due to moving to yet another pot manufacturer Spectrol were bought out by Vishay and Vishay put their prices up considerably on the old Spectrol ranges This inevitably meant that we had to look for alternatives Although the Chinese made BI TT 260P pots fitted into our boards we had problems with getting reliable supplies of these pots Thus the issue 5 VCO was our first 5U board to be revised to Alpha 16mm pots We had been successfully using these pots on our 3U range and our rack projects They offered a good quality pot and at an excellent price The new pots have a smaller shaft and a smaller diameter mounting bush The pot mounting holes in the front panel have had to be reduced accordingly We also had to say goodbye to our trusty SSM2210P matched NPN transistor pair Prices had been rising steadily over the last couple of years and in late 2009 Analog Devices the manufacturers of the SSM line decided to cease production We turned to the superb THAT300 Although a quad NPN array and twice as big as we needed the price is good and quality outstanding An added benefit of this is that the Schmitz Rbe compe2. down The reason for this is that fast pulse width modulation no longer adds thumping to the audio output ie fast EG sweeps of PW will sound great All outputs have an output impedance of roughly 1K The pulse output is also switchable between centre modulated and edge modulated forms of pulse width modulation Most VCOs will only offer edge modulated in which only one edge of the pulse wave is affected by the pulse width pot or modulating CV The Oakley VCO allows you to modulate either one edge edge or both centre In fixed pulse width applications this generally makes no audible difference However when used with fast moving modulating CVs the difference in timbre is apparent A high impedance synchronisation input is provided to prematurely reset the VCO waveform With this you can force the VCO s operating frequency to that of an external sawtooth signal say from another VCO module This input is level sensitive so hard sync is possible with inputs of about 3V or above Inputs below this will cause only occasional synchronisation leading to interesting harmonic structures Please note that to cause hard sync effects the master sync signal must be a sawtooth falling ramp shape waveform of 10V peak to peak The slave VCO will not sync to a ramp waveform which typically has a rising ramp and does not feature the fast rising edge the VCO needs to lock on to These ramp waveforms are in my opinion erroneously cal
3. LSE WIDTH pot to give you a square wave This will be somewhere near the middle of its travel A square wave sounds hollower and less buzzy than the pulse wave so it should be easy to find Now set the PWM type switch to CENTRE It ll probably change the tone of the output signal Adjust the SYM T trimmer so that you can again hear the square wave Flick between the two modes to confirm that you have a square wave in each switch position SYM S and SHP S Plug the sine output into an amplifier and use your ears for this one Set the VCO to make a lowish note around 200Hz will do Adjust SHAPE until the sine output sounds pure Its shouldn t be too buzzy or too hollow Then go back and adjust the SYM S trimmer to get it really pure You may need to bounce back and forth between the two trimmers until you get a good sound Its not essential to get this right just set it so you get a nice sounding output It s easier to do than to explain Now you have set up your VCO and you are ready to go Final Comments I hope you enjoy using the Oakley VCO If you have any problems with the module an excellent source of support is the Oakley Sound Forum at Muffwiggler com Paul Darlow and I are on this group as well as many other users and builders of Oakley modules If you have a comment about this user manual or have a found a mistake in it then please do let me know Last but not least can I say a big thank you to all of you who helped and i
4. SU Oakley Modular Series Voltage Controlled Oscillator The one of three VCO module User Manual V6 0 5 Tony Allgood B Eng PGCE Oakley Sound Systems CARLISLE United Kingdom COARSE EXP FM PWM i er 1 0CT EXP FM LIN FM 000 SINE PULSE 0000 OAKLEY MODULAR SYSTEMS VOLTAGE CONTROLLED OSCILLATOR Introduction This is the User Manual for the issue 5 and issue 6 VCO 5U module from Oakley Sound This document contains an overview of the operation of the unit the history of the various board issues and all the calibration procedures For the Builder s Guide which contains information on how to construct the module from our PCB and parts kits please visit the main project webpage at http www oakleysound com vco htm For general information regarding where to get parts and suggested part numbers please see our useful Parts Guide at the project webpage or http www oakleysound com parts pdf For general information on how to build our modules including circuit board population mounting front panel components and making up board interconnects please see our generic Construction Guide at the project webpage or http www oakleysound com construct pdf The Oakley One of three VCO Module The Oakley One of Three is a voltage controlled oscillator module that was inspired in part by the VCO design of the later MiniMoogs In this module I decided to create a VCO that sounded good and performe
5. andard Sergio Franco technique used on the earlier issues is now fixed to compensate only for the FET discharge time Dave Rossum s technique for compensating for the bulk emitter resistance Rbe of the NPN pair is now added with variable depth controlled by the new HFT trimmer Constant zero average output voltage from the pulse wave This is achieved by considerable changes to the older simple design The board has four Spectrol pots instead of three Omeg ones This makes the board less cramped since the board is now longer The solder pads for the jack sockets now are on standard sized solder pads 0 1 headers are still provided for those of you who like them although the main reason for keeping these is the Orbital The new board layout required a new modular faceplate to be made for the module Issue 4 Boards had the following features added Major mechanical changes The module is now constructed from three PCBs and features solderless interconnects This facilitates easy construction The board set can still be used with the issue 3 front panel design Spectrol 248 pots are now used throughout the module Change to the high frequency tracking HFT circuitry to include Rene Schmitz s improved take on the Rossum method of compensating for Rbe Change to the way the fine tune pot s CV was handled The single metal film 10M resistor was replaced by a simple resistor network 10M 1 resistors are getting hard to come by these days
6. d well enough to keep up with the digital oscillators of modern day synthesisers The VCO features sawtooth pulse triangle and a low distortion sine output The duty cycle of the pulse output may be controlled directly by a PCB mounted pot and also an external voltage the sensitivity being controlled by another PCB mounted pot The frequency of the VCO can be controlled by two PCB mounted pots one for fine the other for coarse adjustment These four pots are designed to be fitted to the main board and when special pot brackets are used the PCB can be firmly supported to the front panel The output levels for the sawtooth sine and triangle are standardised at SV ie 10V peak to peak The pulse wave output is also 10V peak to peak but the peak levels vary with pulse width The Oakley VCO uses an interesting technique to maintain the average voltage over one cycle to zero volts This new circuit essentially adds an offset to the pulse output to compensate for the non zero average voltage for any pulse wave that isn t a square wave Ordinarily one would see average DC values varying from 5V to 5V as the PW is swept from one end to the other In the new VCO this average level is kept at zero This means that for narrow pulses you now have a wave that goes from just below OV down to just below 10V up For square waves you have the usual 5V up and 5V down For wide pulses you have a wave that is just below OV up and just below 10V
7. e fitted if you are using the module with a Synthesizers com system In this case the PWR header is not fitted The PWR header is a six way 0 1 MTA but with the pin that is in location 2 removed In this way location 3 is actually pin 2 on my schematic location 4 is actually pin 5 and so on Power Location number Schematic Pin number 15V 1 1 Missing Pin 2 5V 3 2 Module GND 4 3 15V 5 4 Not connected 6 5 5V is not used on this module so location 3 pin 2 is not actually connected to anything on the PCB If the PWR2 header is fitted then pins 2 and 3 of PWR are linked together This connects the panel ground with the module ground Calibration You should use a proper trimmer tool for the adjusting of all four multiturn trimmers Vishay Bourns and others make trimmer adjusters for less than a pound Before you calibrate you should make sure that the HFT trimmer is adjusted so that the HFT circuitry is turned off To do this you must disconnect the module from the power supply and then with a resistance meter measure between the top pin of R20 and pin 4 of U4 Turn the HFT trimmer until this reading drops to zero or near zero ohms Now power up the module and make sure it has been powered up for at least twenty minutes prior to calibration Also it is a good idea to have the room temperature close to what it would normally be when playing your modular PSU Adjust the trimmer PSU to give 10 00V at TP1 The voltage i
8. led sawtooth by some manufacturers However a simple inverting circuit will be sufficient to turn the waveform around the right way so it can be used as a sync master The VCO supports the standard 1 00V octave exponential voltage to frequency relationship However a linear control input is also provided for constant depth frequency modulation Temperature compensation is performed by using a matched transistor pair in the exponential convertor and a high quality temperature sensitive resistor The Oakley CV gate Buss You really should think about using the Oakley Buss if you have a medium sized Oakley system Using the Oakley Dizzy board it allows the keyboard control voltage KCV and Gate signals to be piped around the back of the modular s case along with the power supply rails Any VCO and VCF can be connected to the Oakley Buss s KCV line and this will save you having to patch KCV to every module that needs it Inserting any patch lead into the 1V OCT socket will override the CV bus line connection The gate signals are treated similarly to the KCV line but for use with the ADSRs and other envelope generator modules The Oakley CV gate buss uses a common three way 0 1 Molex KK header to carry the two signal lines around your modular A third as yet unused connection is also present for future expansion although typically this is taken to ground on the Dizzy board More information can be found in the Dizzy Builder s Guide VCO i
9. ng left empty and no other wires needed On no account should an interconnect with all three wires fitted be used to connect the Oakley Buss to any module The middle location pin 2 is ground on the module and this should not be connected to the Dizzy or midiDAC modules Connecting the ground of a module to the Dizzy ground in this way may induce earth loops and other problems Oakley VCO Issue Changes For those interested the Oakley VCO has evolved slowly over the last eleven years Issue 1 The project started in 1999 and the VCO is based primarily on the third series Minimoog VCO with plenty of additions eg in built 10V reference sync different exponential convertor and summing stage sine wave output pulse width selection output buffering Omeg Eco 16 pots Temperature compensation was generally provided by a 3000ppm K 900mW film resistor This was later upgraded to the KRL wirewound types for last ten or so boards that were sold Issue 2 Boards had the following features added Added 10V reference to go with the 10V internal reference voltage already on issue 1 This stabilises absolute pitch drift so that supply rail potential doesn t affect the pitch of the VCO All pitch pots use the 10V references The range of the TUNE trimmer was reduced and this was coupled with a reduction in the quiescent operating frequency Added SYNC input buffer circuit This has the advantage of providing a high impedance input The old is
10. nsation can be done within the same device as the exponential NPN pair Synthesizers com power header added to the board Issue 6 Boards had the following changes The old style 0 2 ceramic capacitors have been replaced with the newer 2 5mm type Added protection diodes to the THAT300 exponential converter to prevent possible long term damage if the Linear FM input was taken very heavily negative Improved HFT compensation circuitry Moved top pot closer to the edge of the PCB so that it no longer needs a metal shim washer on the inside of the panel Power supply requirements The design requires plus and minus 15V supplies The power supply should be adequately regulated The current consumption is about 30mA for each rail Power is routed onto the PCB by a four way 0 156 MTA156 type connector or the special five way Synthesizers com MTA100 header Power connections MOTM and Oakley The PWR power socket is 0 156 MTA 4 way header This system is compatible with MOTM Power Pin number 15V 1 Module GND 2 Earth PAN 3 15V 4 The earth pan connection has been provided to allow the ground tags of the jack sockets to be connected to the powers supply ground without using the module s OV supply Earth loops cannot occur through patch leads this way although screening is maintained Of course this can only work if all your modules follow this principle Power connections Synthesizers com The PWR2 power socket is to b
11. nspired me Thanks especially to all those nice people on the Synth diy and Analogue Heaven mailing lists and those at Muffwiggler com Tony Allgood at Oakley Sound Cumbria UK January 2011 updated April 2012 No part of this document may be copied by whatever means without my permission
12. octave turn the trimmer to make the top note even higher I always adjust V OCT on the high note of any interval and only adjust the front panel Tune pot on the lower This will probably require some patience and plenty of twiddling of the front panel controls as well But you will get there Once you get the hang of it its easy I can do it in about one minute but I ve had a lot of practice Now leave it on for a further 20 minutes and then check the scaling again Adjust if necessary HFT This is the high frequency tracking trimmer and it compensates for the slight flattening of pitch at when running the VCO at high frequencies If you don t go above 4kHz that often there is a good chance you won t even have to touch this one If you only have a small keyboard use the keyboard s octave transpose setting and the module s coarse tune control to get the VCO playing a really high note For setting the HFT I work between the two As of 7040Hz and 14 080Hz However you can ignore the actual pitch it s the interval we are wanting to get right Once you have set up the perfect octave at these frequencies then check down at the lower end that everything is still responding to 1 V octave Remember if you have skimped on the V OCT trimming no amount of tweaking of the HFT will get it to play in tune If your digital tuner will not track at very high frequencies then a good trick is to use an octave divider plug in or module For each octave di
13. s measured between TP1 and a handy ground OV point For the ground point I use either the square pad on the pot board just under the word LINK or the lower lead of the temp co resistor which is near the word R30 on the PCB V OCT Use this to generate a perfect 1 V octave scaling This trimmer will need to be adjusted along with the fine and coarse pots on the front panel You will need a digital frequency counter or my favourite a guitar chromatic tuner or tuner plug in Some people use another keyboard or a calibrated VCO and listen to the beats but that can take longer Plug your midi CV convertor or 1 V oct keyboard into the 1V octave input of the VCO Play a lowish note on the keyboard then go two octaves higher Adjust V OCT until the interval is exactly two octaves I normally try to work between the two As of 220 0Hz and 880 0Hz However please note we are only setting the interval and not the actual frequency It does not have to be a perfect A when A is being pressed on the keyboard It could be an F or whatever The important thing is that we are setting the musical gap between the notes If you do need to alter the pitch of the VCO to help you use the front panel controls only Leave the TUNE trimmer until later For any interval if you find the higher note is flat then turn the V OCT trimmer to make it flatter still This actually reduces the range between the two notes Conversely if you find your interval is greater than an
14. ssues 4 5 and 6 support the Oakley CV gate buss natively Previous issues had the CV buss being connected to the module via a wire tail attached to the 1 V octave socket s normally closed NC lug The socket board features an optional three way header that can be fitted to allow direct connection to the CV gate buss on an installed Oakley Dizzy system or with our VCO Controller module If not required a simple two way jumper like those used on computer motherboards can be fitted to connect between pins 1 and 2 By fitting this jumper the 1 V octave socket is shorted to ground when a jack plug is not inserted thus reducing pick up from stray signals bbb There are four headers on the VCO module s socket board Three of them will be fitted with connectors that go to other parts of the module The Oakley Buss is the unconnected three way header on the right If you are not intending to use it it should have a small two way jumper link inserted across pins I and 2 Pin I is the one furthest to the left and nearest the other big connector Although the Oakley Buss header is a three way connector the actual interconnect you need to use has only one wire fitted The Oakley VCO is connected only to pin 1 of the Oakley Buss This is the connection carrying KCV This means you need to use only a single wire that is terminated in a 3 way housing at either end The first location of the housing pin 1 is the only one used with the other two locations bei
15. sue had a 10K input resistance which caused a slight drop in amplitude to the other master VCO connected to the SYNC input An additional benefit is that unwanted cross coupling between two or more slave VCOs was eradicated With the older VCOs any two slave VCOs tended to sync to each other as well as the master Interesting effect though I swapped the positions of the power supply regulator with the CV summer circuitry This enabled me to move the two tuning multiturn trimmers to the edge of the board The old issue 1 board had these parts in the centre of the PCB and they were impossible to trim when the board was fitted into the Oakley Orbital monosynth Moving the trimmers to the edge means that we can now use side adjustable trimmers in the Orbital to facilitate easy tuning with the boards in situ This does not affect the modular set up in any way in that we will continue to use top adjustable trimmers as before As it turns out no issue 2 boards ever made it into the Orbital project The pitch spacing of the polyester capacitors was changed from 0 3 to 5mm This was in line with other Oakley boards Added separate triangle and sine wave offset trimmers This meant that switching to centre on the PWM source switch would not affect the mark space ratio of the square wave output Issue 3 Boards had the following features added Sine wave purity increased Two high frequency tracking compensation networks instead of just one The st
16. vision you reduce the frequency by two This divided output should be low enough for your tuner to work properly TUNE This sets the range over which your VCO acts Set the Coarse pot to its minimum setting and set the Fine pot to its middle position Play the lowest note on your keyboard Now adjust the TUNE trimmer until the note that you can hear is equivalent to your lowest note minus three semitones or so That is if your bottom note is a C then adjust TUNE so that you get a A In normal operation the Coarse Tune pot would be just off its minimum value to set the correct note You may want to compare it to another keyboard module to make sure that you have set it to the right octave As far as I am aware there is no standard amongst modular systems that defines what pitch corresponds to what CV input However I choose to make my VCOs produce middle C C4 at their typical settings when the 1 V octave input is at 5 00V Thus I would expect the VCO to be producing 261 6Hz when its KeyCV input is 5V the coarse tune pot is set to slightly above the minimum and the fine tune pot in the middle SHP T Play an A an octave above middle C Adjust SHP T so that the triangle output sounds smooth You will know when it is right If you have a scope adjust SHP T so that the sharp steps disappear from the output SYM T Set the PWM TYPE switch to EDGE Listen to the pulse output at any frequency that s comfortable to listen to Now turn the PU
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