Voltage source components on the board

So this weekend I have been inputting schematics into 'tinyCAD' and then exporting the resultant NetLists to a bit of software called VeeCAD. This is a veroboard layout package. It won't do the work for you but it'll tell you when you have got it wrong. A design package like this allows us to optimise for physical space on the veroboard. The first circuit has been laied down, all that is needed is that the controls on the front panel be wired in, and the first module will be complete.
(the second module is CV splitter and mixer, allowing frequencies based on the root note to be generated, to save space in my rack I have decided to combine these 2 functions. After that we'll get to actually getting the thing to make some noise!)

Building the first panel

Covering the panel in masking tape will stop marking while being held in the vice. This panel has been marked up to show the exact place for each component. A centre punch (made out of an old filed down screw driver) was used before some honking great big holes were drilled in the panel.

 The components were then added (see photos below) with some consideration taken to make sure they were clear of the edges so as not to impede in the way of getting in the way of the case.

Now we know how many components we have on the front panel, we can start designing exactly what circuit we need for the board.

Choosing the right panel size

So its about time I started picking the right sized panel for the first module. The first module I need to be a voltage source for the oscillator. I have decided that for a voltage source I will be wanting at least one main control voltage (+1v -> +10v), and also I thought it would be nice to have a couple of low voltages (0v -> +1v and 0v -> +2v) that can be mixed with a main control voltage and used as an offset. There also needs to be some kind of gate, so I have opted for the middle size panel showed in this image. The panels I have got are 8HP, 10HP and 14HP. To fit at least 4 pots and 4 jacks, the smaller panel would be too small. The next step will be to drill holes.

Sonic Wonderland: A Scientific Odyssey of Sound

I heard an interview on radio 4 yesterday with a guy called Trevor Cox. He is a sound engineer working at Salford Uni, and he has just written a book called Sonic Wonderland. It was pitched as a travel guide, but instead of the destinations being visual feasts they are auditory! It sounds wonderful, can't wait for it to come out!

Ice Music Festival

The scandinavian "Ice Music Festival" consists of improvisations on instruments made of ice. It's the kind of thing that deserves a very nice sound system to listen to it on :)

   Some of the marimba like instruments are fantastic, not only do they have a beautiful resonance but the sustain on them is phenomenal. One of the key individuals is called "Terje Isungset" whose music is available on spotify.

Radio 4 have done a wonderful documentary on it.

Power

There we go, easy peasy, one power bus, giving us 24v, Regulated 12v and regulated 5v. Now for something a little more interesting

Making things easier

OK, so it looks like I have taken some bad advice on buying a power supply. I think a +24v PSU is going to struggle to supply both +12 and -12v, so for my power bus I'm going to stick to +12 and +5, and if I need negative voltage, then I'll have to do it on a module by module basis. No big deal. What I do lose is compatibility with existing systems, but if Im honest, I am not building a re-salable, integratable project, I am building a cool sounding synth that sounds cool and looks cool! (just so everyone is sure about that... cool)

Negative Voltage

I think I have a problem... This circuit seems like it might give us the +12v and -12v supply we need, but I think the lack of relative GNDs scuppers me. Can anyone help with this?

Synth Project - Concept

Modular Synth

So, I watched I Dream of Wires and I thought I'd build a nice analogue modular synth. I'd like to practice my electronics, and I thought a modular synth might be a nice project that would take us step by step through analogue electronics. The nice thing about it being modular is that each module can be separated from the rest of the system so that the focus can be entirely on the functionality of each module and not a complicated juggling act of balancing circuits operations. I thought I'd blog this (due to several request).

To start this we need a standard to stick by, so that all the modules can operate happily in a common environment.

System Design

Looking at analogue synths, the top end of the market is eurorack, for which I think the Doepfer stuff looks pretty cool, so I thought Id model my system on their. (Why invent a new standard when one already exists, plus there is a lot to be said for compatibility these days!)

Here is an example of the kind of think i'm going for:

So first things first, I need a supplier for the case and the module face plates. I found that the Doepfer stuff all runs on a 3U 19" rack. Schroff are a company that supply this kinda stuff, they also have an ebay store.

Power

Very helpfully, Doepfer provide a lot of information about the basic spec of their system which allowed me to get the information required to build the system environment (or, power supply and chassis)

This diagram specifies +5, +12 and -12 power bar. I've ordered a PSU that'll take 230v AC and kick out +24v DC and give me 3 amps. I don't think I'll need more than 3 amps for this project, but If I find things are going screwy later because I don't have enough juice, it's a simple change to make.

To get the power I want I'm going to have to use a DC-DC converter and some Voltage Regulators. I found a converter on RS that'll take +24 and kick out +15 and -15. It's called a TEL32423 and is quite expensive, but I can't see another way of getting negative voltage onto my system. (I'm guessing the negative will be important for when I try and generate sine waves).

For each connector I will need a +12 VReg and a -12 Vreg. (most vregs need an overhead of a few volts to work, which is why I need a 24V PSU stepped down to 12V), and because I want each module to be correctly isolated, I think I need the vregs for each unit in the bus. Instead of building this power isolation on each board I want to keep it on the power bus, because it makes sense to keep functionality organised and together. So I've ordered a bunch of them. The connectors on this standard bus are 10 way "IDC" connectors, so I have ordered a bunch of plugs, sockets and cables also.

The CV and Gate on the bus are a lovely idea to potentially remove a little bit of the patching from the final front panel. Electrically there is nothing going on here, this is just a bus that allows modules to communicate with other modules without using patch leads. CV is designed for the control voltage (to control pitch) and Gate is designed for the 'On/Off' signal, although these can be used for anything. To isolate these there should be jumpers on the board so this can be configured depending on the system. I am not even sure how useful this will be, but as we are adhering to the standard it doesn't do any harm to do things properly, it might even come in handy later, who knows.

So with all the components on the way, next we will turn to the breadboard to check that we are getting the voltages that we expect before building the power bus board.