Non-standard Circuits: Jazz For Electrons

How creative are you when you make your circuit boards? Do you hunt around for different materials to use for the board? As long as it’s an insulator and can handle the heat of a soldering iron, then anything’s fair game. Or do you use a board at all? Let’s explore some options, both old favorites and some you may not have seen before, and see if we can get our creative juices flowing.

Transparent Circuit Boards

Let’s start with the desire to show more circuit and less board. For that we can start with [CNLohr]’s circuits on glass, usually microscope slides. What’s especially nice about his is that he provides detailed videos of the whole process, including all the failed things he tried along the way. Since he didn’t start with copper clad board, he instead glued his copper sheet to the glass using Loctite 3301. That was followed by the usual etching process, though with plenty of gotchas along the way.

In the end, he made a number of circuits, including an LED clock with the LEDs on the glass itself, and even attempted leading the community in making a glass keytar. The latter didn’t work out, but the resulting glass circuits are a work of art anyway.

What about making a transparent circuit board out of acrylic? [Frank Zhao] attempted just that by laser cutting troughs into the acrylic for the traces, and then drawing in nickel ink. But something in the ink ate into the acrylic, and as if that wasn’t bad enough, the voltage drop across the nickel was too high for his circuit. Suggestions were made in the comments for how to solve these problems, but unless we missed it, we haven’t seen another attempt yet.

But we’ve only just begun. What if you wanted even more transparency?

Circuit Boards In Air

One way to get more transparent than glass or acrylic is to do away with the board altogether. Historically this is called point-to-point construction, a term which predates printed circuit boards. The name for it we see more often here on Hackaday is a Dead Bug circuit, a name that comes from the appearance you get when you install a component upside down and solder to its legs.

[matseng] was bored one afternoon and made a Dead Bug version of the Little Wire circuit, an AVR programmer with a minimal parts count. After an hour or two using a fine tipped soldering iron, 0.4 mm solder and a stereo microscope he came up with the very elegant wire and parts only circuit shown here. The dead bug is the SOIC version of an ATtiny85.

However, these types of circuit don’t all look like dead bugs. Some far from it. Among the most spectacular has to be [Gislain Benoit]’s circular digital clock made up of thousands of components that keeps time using the North American 60 Hz mains voltage cycle.

Surprisingly not represented here on Hackaday, perhaps we missed it back around 2009, is the boardless artistic circuitry of [Peter Vogel]. These actually work too. Some monitor light levels and respond with
changing sounds, some light up, and some have rotating propellers.

Pyrite volumetric circuits software
Pyrite volumetric circuits software

[Anderson] has done a lot of work towards taking dead bugging to the next level, referring to these as volumetric circuits. He’s written software, called Pyrite, for designing them. It lets you draw the normal 2D version, then test it in a simulator, and then it folds the circuit into a 3D version for you to use as a guide. He’s also done some R&D into 3D connectors for prototyping.

Encapsulated Dead Bug Circuit

Crystal cMoy headphone amplifier
Crystal cMoy headphone amplifier

Then there’s the combination of transparent board and Dead Bug circuit. A perfect example of that is [Rupert Hirst]’s beautiful headphone amplifier circuit encapsulated in crystal clear resin. If you’ve worked with casting this much resin at once then you’ll know that it can potentially reach high temperatures as the resin cures. In this case temperatures reached a nail-biting 108°C while the capacitors were rated for 125°C. There was also the danger of resin leaking into the jack cases. To prevent that, [Rupert] first hardened a little resin around wherever leaks could occur. The result was a functioning amp and a work of art.

Circuits On 3D Surfaces

Next up is putting your circuit on boards that are far from board-shaped. [FESTO]’s bionicANTs ant army is one such example. The boards are 3D printed ant bodies. The circuit is applied using 3D MID, a process where the body is printed in a special non-conductive material onto which a laser draws out the traces. That’s followed by dipping the body in various baths to apply copper, nickel and gold layers.

The only other example our searches turned up of circuits involving mostly basic components being applied to 3D printed objects was a research project called SurfCuit. This one included software similar to the one [Anderson] worked on for Dead Bug circuits. The software allows you to drape a 2D circuit onto a 3D model. It then adds channels and holes to the model as needed. Once 3D printed, you then apply the actual wires and components to those channels and holes.

As we said, we had trouble finding these. If you’re aware of any more circuits on 3D printed objects, please share them in the comments below.

Circuits On Clothes

That brings us to circuits on clothing. In this case the wiring is often conductive thread, woven into the cloth itself. Of course it’s faster to do this by machine and we’ve seen a version of this from Cynthia Design Studio that lays down the three parallel traces you need to run WS2812 LEDs.

Conductive thread used in fabrics then connects components sewn onto the cloth. Most often this technique is used to add LEDs, as [Martijn] did with his climbing jacket. There, the LEDs change color based on the altitude as determined by a barometric sensor and other components. But there are other uses too. One such is [Afrdt]’s EMF wave detecting dress that plays back the signals using a vibrating motor, and as sound to earbuds that can be plugged into a collar.

Closing The Circuit

In this article we’ve been highlighting the artistic, the creative, and even the jaw droppingly beautiful. But this sort of circuitry can go the other way too, as our [Dan Maloney] points out in his article about getting ugly with circuits.

In any case, hopefully that’s gotten your creative juices flowing for your next circuit. Naturally we couldn’t fit every sample of awesomeness into one article, so let us know of any others that you particularly fancy, or better yet, that you’ve made yourself!

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