Qualcomm Introduces The Arduino Uno Q Linux-Capable SBC

Generally people equate the Arduino hardware platforms with MCU-centric options that are great for things like low-powered embedded computing, but less for running desktop operating systems. This looks about to change with the Arduino Uno Q, which keeps the familiar Uno formfactor, but features both a single-core Cortex-M33 STM32U575 MCU and a quad-core Cortex-A53 Qualcomm Dragonwing QRB2210 SoC.

According to the store page the board will ship starting October 24, with the price being $44 USD. This gets you a board with the aforementioned SoC and MCU, as well as 2 GB of LPDDR4 and 16 GB of eMMC. There’s also a WiFi and Bluetooth module present, which can be used with whatever OS you decide to install on the Qualcomm SoC.

This new product comes right on the heels of Arduino being acquired by Qualcomm. Whether the Uno Q is a worthy purchase mostly depends on what you intend to use the board for, with the SoC’s I/O going via a single USB-C connector which is also used for its power supply. This means that a USB-C expansion hub is basically required if you want to have video output, additional USB connectors, etc. If you wish to run a headless OS install this would of course be much less of a concern.

2025 Hackaday Supercon: More Wonderful Speakers

Supercon is just around the corner, and we’re absolutely thrilled to announce the second half of our slate! Supercon will sell out so get your tickets now before it’s too late. If you’re on the fence, we hope this pushes you over the line. And if it doesn’t, stay tuned — we’ve still got to tell you everything about the badge and the fantastic keynote speaker lineup.

(What? More than one keynote speaker? Unheard of!)

And as if that weren’t enough, there’s delicious food, great live music, hot soldering irons, and an absolutely fantastic crowd of the Hackaday faithful, and hopefully a bunch of new folks too. If you’re a Supercon fan, we’re looking forward to seeing you again, and if it’s your first time, we’ll be sure to make you feel welcome. Continue reading “2025 Hackaday Supercon: More Wonderful Speakers”

Can A Coin Cell Make 27 Volts?

We have all no doubt at some point released the magic smoke from a piece of electronics, it’s part of what we do. But sometimes it’s a piece of electronics we’re not quite ready to let go, and something has to be fixed. Chris Greening had a board just like that, a 27 volt generator from an LCD panel, and he crafted a new circuit for it.

The original circuit (which we think he may have drawn incorrectly), uses a small boost converter IC with the expected inductor and diode. His replacement is the tried and tested joule thief, but with a much higher base resistor than its normal application in simply maintaining a battery voltage. It sucks 10 mA from the battery and is regulated with a Zener diode, but there’s still further room for improvement. Adding an extra transistor and using the Zener as a feedback component causes the oscillator to shut off as the voltage increases, something which in this application is fine.

It’s interesting to see a joule thief pushed into a higher voltage application like this, but we sense perhaps it could be made more efficient by seeking out an equivalent to the boost converter chip. Or even a flyback converter.

Smart Bulbs Are Turning Into Motion Sensors

If you’ve got an existing smart home rig, motion sensors can be a useful addition to your setup. You can use them for all kinds of things, from turning on lights when you enter a room, to shutting off HVAC systems when an area is unoccupied. Typically, you’d add dedicated motion sensors to your smart home to achieve this. But what if your existing smart light bulbs could act as the motion sensors instead?

Continue reading “Smart Bulbs Are Turning Into Motion Sensors”

A Childhood Dream, Created And Open Sourced

Some kids dream about getting a pony, others dream about a small form factor violin-style MIDI controller. [Brady Y. Lin] was one of the latter, and now, with the skills he’s learning at Northwestern, he can make that dream a reality — and share it with all of us as an open source hardware project.

The dream instrument’s name is Stradex1, and it’s a lovely bit of kit. The “fretless” neck is a SoftPot linear potentiometer being sampled by an ADS1115 ADC — that’s a 16-bit unit, so while one might pedantically argue that there are discreet frets, there’s 2^15 of them, which is functionally the same as none at all. Certainly it’s enough resolution for continuous-sounding pitch control, as well as vibrato, as you can see at 3:20 in the demo video below. The four buttons that correspond to the four strings of a violin aren’t just push-buttons, but also contain force sensors (again, sampled by the 16-bit ADC) to allow for fine volume control of each tone.

A few other potentiometers flesh out the build, allowing control over different MIDI parameters, such as what key [Brady] is playing on. The body is a combination of 3D printed plastic and laser-cut acrylic, but [Brady] suggests you could also print the front and back panels if you don’t happen to have a laser cutter handy.

This project sounds great, and it satisfies the maker’s inner child, so what’s not to love. We’ve had lots of MIDI controllers on Hackaday over the years — everything from stringless guitars  to wheel-less Hurdy-Gurdies to say nothing of laser harps galore — but somehow, we’ve never had a MIDI violin. The violin hacks we have featured tend to be either 3D printed or comically small.

If you like this project but don’t feel like fabbing and populating the PCB, [Brady] is going to be giving one away to his 1000th YouTube subscriber. As of this writing, he’s only got 800, so that could be you!

Continue reading “A Childhood Dream, Created And Open Sourced”

A Lorenz Teletype Shows Us Its Secrets

When we use the command line on Linux, we often refer to it as a terminal. It’s a word with a past invoking images of serial terminals, rows of green-screened machines hooked up to a central computer somewhere. Those in turn were electronic versions of mechanical teletypes, and it’s one of these machines we’re bringing you today. [DipDoT] has a Lorenz teletype from the 1950s, and he’s taking us through servicing and cleaning it, eventually showing us its inner workings.

The machine in question had been in storage for many years, but remained in good condition. To be this long out of use though meant it needed a thorough clean, so he sets about oiling the many hundreds of maintenance points listed in a Lorenz manual. It’s a pleasant surprise for us to see keyboard and printer unit come away from the chassis for servicing so easily, and by stepping it through its operation step by step we can see how it works in detail. It even incorporates an identifier key — think of it as a mechanical ROM that stores a sequence of letters — which leads him to believe it may have come from a New York news office. The video is below the break, and makes for an interesting watch.

He’s going to use it with a relay computer, but if you don’t have one of those there are more modern ways to do it.

Continue reading “A Lorenz Teletype Shows Us Its Secrets”

A New Cartridge For An Old Computer

Although largely recognizable to anyone who had a video game console in the 80s or 90s, cartridges have long since disappeared from the computing world. These squares of plastic with a few ROM modules were a major route to get software for a time, not only for consoles but for PCs as well. Perhaps most famously, the Commodore VIC-20 and Commodore 64 had cartridge slots for both gaming and other software packages. As part of the Chip Hall of Fame created by IEEE Spectrum, [James] found himself building a Commodore cartridge more than three decades after last working in front of one of these computers.

[James] points out that even by the standards of the early 80s the Commodore cartridges were pretty low on specs. They’re limited to 16 kB, which means programming in assembly and doing things like interacting with video hardware directly. Luckily there’s a treasure trove of documentation about the C64 nowadays as well as a number of modern programming tools for them, in contrast to the 80s when tools and documentation were scarce or nonexistent. Hardware these days is cheap as well; the cartridge PCB and other hardware cost only a few dollars, and the case for it can easily be 3D printed.

Burning the software to the $3 ROM chip was straightforward as well with a TL866 programmer, although [James] left a piece of memory management code in the first pass which caused the C64 to lock up. Removing this code and flashing the chip again got the demo up and running though, and it’ll be on display at their travelling “Chips that Changed the World” exhibit. If you find yourself in the opposite situation, though, we’ve also seen projects that cleverly pull the data off of ancient C64 ROM chips for preservation.