The lightsaber is an iconic weapon from the Star Wars franchise, designed in all sorts of shapes and colors. Several fan-made versions have been built as well, quite a few of which use the almost ubiquitous neopixel. [Tirenoth] decided to build his first lightsaber using a series of neopixels, but decided on a unique build method.
Instead of the usual strip of neopixels, [Tirenoth] chose to use a bunch of neopixels in the 5mm LED form-factor. [Tirenoth] soldered each LED’s 5v pins and GND pins to the same pins on the next, rotating each LED 180 degrees, building a tower of pixels. The data in and out pins are soldered to the next (and previous) LED as well. This allows the series of LEDs to be a bit more stable physically, and allows them to be stacked close together, one on top of the other.
To control the neopixels, a Proffieboard is used, an open-source lightsaber controller. The Proffieboard uses an STM32 microcontroller and allows you to hook up LEDs or neopixels as well as a speaker. Its open-source software allows the animation of the pixels and the playing of sounds. It’s designed specifically for lightsaber builds and is programmed via the Arduino IDE.
[Tirenoth] has some nice pictures of the build in process and, of course some nice pics of the final result. He suggests that the blade would be the first to break in battle, though. There’s been a few lightsaber builds over the years, like this lightsaber with rave mode, or this lightsaber made with real lasers.
Wood. Specifically, certain types of tone woods; woods that impart a certain tone. That’s what guitars are made of. And occasionally, plastic, or metal, or fibreglass or, well, anything. [_forwardaudio_] built his out of noodles, because, why not?
Well, not completely out of noodles. Epoxy is used to give some strength to the noodles, because, despite the fantastic tone that noodles impart to the guitar, they’re not known for their strength. The epoxy helps keep the noodles in place, focusing their noodly tone.
To add a bit of punch to the look of the guitar, the back and front of the body have UV powder blended in, blue on the front and green on the back. Once the guitar was assembled, a set of UV strings were added as well, to add even more glowy goodness.
In the video (after the break) the build process is shown along with the simplified, volume only, wiring. At the end, [_forwardaudio_] noodles around on the guitar a bit.
I’ll show myself out.
If noodles aren’t your thing, maybe you’d prefer 3D printing an extended fretboard for your guitar, or to build yourself a 12 foot long guitar.
Continue reading “Guitar Made From Noodles Glows In The Dark”
From building your own analog effects pedal to processing audio through micro controllers, a lot of musicians love building their own boxes of sound modification. In his entry for the 2019 Hackaday Prize, [Craig Hissett] has a project to build an all-in-one multi-effects stomp box.
At the center of the box is a Raspberry Pi with an AudioInjector stereo sound card. The card takes care of stereo in and out, and passing the signal to the Pi. The software is Modep, an open source audio processor that allows the setup of a chain of digital effects plugins to be run on the Pi. After finding some foot switches, [Craig] connected them to an Arduino Pro Micro which he set up as a MIDI device that sends MIDI messages to the Modep software running on the Pi.
There are still a few steps to go, but [Craig] has the basic layout covered. Next up is wiring it up and building a proper case for it, as well as working on latency. A few years ago, another multi-effects stomp box was featured in the Hackaday Prize, and last year, this multi-effects controller was featured.
The clapperboard is a device used in video to synchronize audio and video. Its role in movies is well known and its use goes back in one form or another to the 1920s. [Gocivici] is a big movie fan and created a clapperboard that is able to print out posters of recently announced movies when the clapper is clapped.
The poster is not a big, full color job, but rather a black and white one, roughly the size of a movie ticket. [Gocivici] keeps his movie tickets in a journal and wanted to be able to keep small posters in there along with them. A thermal printer is used to print the poster along with the title, the release date, and some information about the movie. In addition to the printer, the hardware involved is a Raspberry Pi, a switch, and an LED. The clapperboard itself is 3d printed and then painted. A bit of metal is used to keep the clappers apart and give a bit of resistance when pressing them together. A nice touch is a metal front, so you can use magnets to keep your posters on the board.
[Gocivici] has detailed build instructions up along with a video (available after the break) showing the printer in action. The 3d models are available as well as the code used to create the posters after grabbing data from TMDb. If you need your clapperboard to be as accurate as possible, take a look at this atomic clock clapperboard.
Continue reading “This Clapperboard Prints Movie Posters”
We love our clocks around here and we love nixie tubes as well. The combination of the two almost seems to be a no-brainer. With the modern twist of an ESP8266, Reddit user [vladco] built a minimalist nixie tube clock.
The build starts with the nixie tubes, Russian In4s, each one mounted on its own small circuit board. Each board is chained together and they’re mounted on a wooden frame. The frame is mounted inside a nice wooden case which was designed in Fusion 360 and milled out of oak at a local hackerspace.
There are no controls on the case. No buttons or knobs. This clock is set via the EPS8266 which gets the time and updates the shift registers that set the numbers on each of the tubes. The clock dims at night so it’s not as bright. [vladco] wrote a web UI to set the time and interact with the tubes.
The code and files for the case and circuit board are available online. The result is a nice, minimalist clock for your desk. There are plenty of clock builds on the site, several built from nixie tubes, including another nixie tube clock with an ESP8266, and another.
Classic games never seem to have gone out of style and with the emulation powers of the Raspberry Pi, there seems to be no end of projects folks have been coming up with. [Chris Mills] project is a great looking monitor to get his Commodore 64 fix by combining the retro looks of a home-made 64-style monitor with the Raspberry Pi.
[Chris] is only interested in Commodore 64 emulation, at least with this project, and wanted something that would fit on a desk without taking up too much room. An eight inch LCD security monitor fit the bill perfectly. [Chris] ended up building a wooden enclosure for the monitor to give it that Commodore look. The monitor, power supply and cable connections fit inside along with speakers; each of these having their inputs on the back. A fan vents in the back as well and the Pi sits outside running the Combian 64 emulation software.
[Chris] has put up some galleries of build pics. The logo from the old Commodore logo is a nice touch. Read over the Hackaday site and you could build your own Commodore 64, or use the Commodore 64 itself to house the Raspberry Pi if you wanted.
The Raspberry Pi is a great platform for running retro video games, and with the addition of some buttons, a TFT screen and some speakers it’s relatively inexpensive and easy to get a working console up and running. If you have access to even a cheap 3D printer, a good-looking DIY console is well within reach for not a lot of money. YouTube user [DIY Engineering] has a bunch of consumer-grade fabrication tools and has designed and built a high-end but still DIY RetroPi gaming console, the RKDR II.
Among the tools that [DIY Engineering] has are both a FDM and DLP 3D printer, a reflow oven, a couple of different CNC machines and a laser cutter. They are all consumer grade, but not necessarily cheap – especially combined! [DIY Engineering] uses Fusion3D to model the case, bezel and circuit board, the latter of which is a 4 layer board designed in Eagle and sent off to be fabbed. The buttons, D-pad, screen and battery are bought off the shelf, but everything else is DIY. Check out the video for the details – the tools used, and the design files, are linked in the information section under the video on YouTube.
Continue reading “Yet Another DIY Handheld Pi Gaming Console”