Hackaday

Normal people binge-scroll social media. Hackaday writers tend to pore through online tech news and shopping sites incessantly. The problem with the shopping sites is that you wind up buying things, and then you have even more projects you don’t have time to do. That’s how I found the MAKE-roscope, an accessory aimed at kids that turns a cell phone into a microscope. While it was clearly trying to appeal to kids, I’ve had some kids’ microscopes that were actually useful, and for $20, I decided to see what it was about. If nothing else, the name made it appealing.

My goal was to see if it would be worth having for the kinds of things we do. Turns out, I should have read more closely. It isn’t really going to help you with your next PCB or to read that tiny print on an SMD part. But it is interesting, and — depending on your interests — you might enjoy having one. The material claims the scope can magnify from 125x to 400x.

What Is It?

A microscope in a tin. Just add a cell phone or tablet

The whole thing is in an unassuming Altoids-like tin. Inside the box are mostly accessories you may or may not need, like a lens cloth, a keychain, plastic pipettes, and the like. There are only three really interesting things: A strip of silicone with a glass ball in it, and a slide container with five glass slides, three of which have something already on them. There’s also a spare glass ball (the lens).

What I didn’t find in my box were cover slips, any way to prepare specimens, and — perhaps most importantly — clear instructions. There are some tiny instructions on the back of the tin and on the lens cloth paper. There is also a QR code, but to really get going, I had to watch a video (embedded below).

What I quickly realized is that this isn’t a metalurgical scope that takes images of things. It is a transmissive microscope like you find in a biology lab. Normally, the light in a scope like that goes up through the slide and into the objective. This one is upside down. The light comes from the top, through the slide, and into the glass ball lens.

Bio Scopes Can Be Fun

Of course, if you have an interest in biology or thin films or other things that need that kind of microscope, this could be interesting. After all, cell phones sometimes have macro modes that you can use as a pretty good low-power microscope already if you want to image a part or a PCB. You can also find lots of lenses that attach to the phone if you need them. But this is a traditional microscope, which is a bit different.

The silicone compresses, which seems to be the real trick. Here’s how it works in practice. You turn on your camera and switch to the selfie lens. Then you put the silicone strip over the camera and move it around. You’ll see that the lens makes a “spotlight” in the image when it is in the right place. Get it centered and zoom until you can’t see the circle of the lens anymore.

Then you put your slide down on the lens and move it around until you get an image. It might be a little fuzzy. That’s where the silicone comes in. You push down, and the image will snap into focus. The hardest part is pushing down while holding it still and pushing the shutter button.

Zeiss and Nikon don’t have anything to worry about, but the images are just fine. You can grab a drop of water or swab your cheek. It would have been nice to have some stain and either some way to microtome samples, or at least instructions on how you might do that with household items.

Verdict

For most electronics tasks, you are better off with a loupe, magnifiers, a zoomed cell phone, or a USB microscope. But if you want a traditional microscope for science experiments or to foster a kid’s interest in science, it might be worth something.

For electronics, you are better off with a metallurgical scope. Soldering under a stereoscope is life-changing. We’ve seen more expensive versions of this, too, but we aren’t sure they are much better.

From Blog – Hackaday via this RSS feed

The seeds of the Internet were first sown in the late 1960s, with computers laced together in continent-spanning networks to aid in national defence. However, it was in the late 1990s that the end-user explosion took place, as everyday people flocked online in droves.

Many astute individuals saw the potential at the time, and rushed to establish their own ISPs to capitalize on the burgeoning market. Amongst them was a famous figure of some repute. David Bowie might have been best known for his cast of rock-and-roll characters and number one singles, but he was also an internet entrepreneur who got in on the ground floor—with BowieNet.

Is There Dialup On Mars?

The BowieNet website was very much of its era. Credit: Bowienet, screenshot

Bowie’s obsession with the Internet started early. He was well ahead of the curve of many of his contemporaries, becoming the first major artist to release a song online. Telling Lies was released as a downloadable track, which sold over 300,000 downloads, all the way back in 1996. A year later, the Earthling concert would be “cybercast” online, in an era when most home internet connections could barely handle streaming audio.

These moves were groundbreaking, at the time, but also exactly what you might expect of a major artist trying to reach fans with their music. However, Bowie’s interests in the Internet lay deeper than mere music distribution. He wanted a richer piece of the action, and his own ISP—BowieNet— was the answer.

The site was regularly updated with new styling and fresh content from Bowie’s musical output. Eventually, it became more website than ISP. Credit: BowieNet, screenshot

Bowie tapped some experts for help, enlisting Robert Goodale and Ron Roy in his nascent effort. The service first launched in the US,  on September 1st 1998, starting at a price of $19.95 a month. The UK soon followed at a price of £10.00. Users were granted a somewhat awkward email address of username@davidbowie.com, along with 5MB of personal web hosting.  Connectivity was provided in partnership with established network companies, with Concentric Network Corp effectively offering a turnkey ISP service, and UltraStar handling the business and marketing side of things. It was, for a time, also possible to gain a free subscription by signing up for a BowieBanc credit card, a branded front end for a banking services run by USABancShares.com. At its peak, the service reached a total of 100,000 subscribers.

Bonuses included access to a network of chatrooms. The man himself was a user of the service, regularly popping into live chats, both scheduled and casually. He’d often wind up answering a deluge of fan questions on topics like upcoming albums and whether or not he drank tea. The operation was part ISP, part Bowie content farm, with users also able to access audio and video clips from Bowie himself. BowieNet subscribers were able to access exclusive tracks from the Earthling tour live album, LiveAndWell.com, gained early access to tickets, and could explore BowieWorld, a 3D interactive city environment. To some controversy, users of other ISPs had to stump up a $5.95 fee to access content on davidbowie.com, which drew some criticism at the time.

Bowienet relied heavily on the leading Internet technologies of the time. Audio and graphics were provided via RealAudio and Flash, standards that are unbelievably janky compared to those in common use today. A 56K modem was recommended for users wishing to make the most of the content on offer. New features were continually added to the service; Christmas 2004 saw users invited to send “BowieNet E-Cards,” and the same month saw the launch of BowieNet blogs for subscribers, too.

Bowie spoke to the BBC in 1999 about his belief in the power of the Internet.

BowieNet didn’t last forever. The full-package experience was, realistically, more than people expected even from one of the world’s biggest musicians. In May 2006, the ISP was quietly shutdown, with the BowieNet web presence slimmed down to a website and fanclub style experience. In 2012, this too came to an end, and DavidBowie.com was retooled to a more typical artist website of the modern era.

Ultimately, BowieNet was an interesting experiment in the burgeoning days of the consumer-focused Internet. The most appealing features of the service were really more about delivering exclusive content and providing a connection between fans and the artist himself. It eventually became clear that Bowie didn’t need to be branding the internet connection itself to provide that.

Still, we can dream of other artists getting involved in the utilities game, just for fun. Gagaphone would have been a slam dunk back in 2009. One suspects DojaGas perhaps wouldn’t have the same instant market penetration without some kind of hit single about clean burning fuels. Speculate freely in the comments.

From Blog – Hackaday via this RSS feed

There was a period in the 1990s when it seemed like the personal data assistant (PDA) was going to be the device of the future. If you were lucky you could afford a Psion, a PalmPilot, or even the famous Apple Newton — but to trap the unwary there were a slew of far less capable machines competing for market share.

[Nick Bild] has one of these, branded Rolodex, and in a bid to make using a generative AI less alluring, he’s set it up as the interface to an LLM hosted on a Raspberry Pi 400. This hack is thus mostly a tale of reverse engineering the device’s serial protocol to free it from its Windows application.

Finding the baud rate was simple enough, but the encoding scheme was unexpectedly fiddly. Sadly the device doesn’t come with a terminal because these machines were very much single-purpose, but it does have a memo app that allows transfer of text files. This is the wildly inefficient medium through which the communication with the LLM happens, and it satisfies the requirement of making the process painful.

We see this type of PDA quite regularly in second hand shops, indeed you’ll find nearly identical devices from multiple manufacturers also sporting software such as dictionaries or a thesaurus. Back in the day they always seemed to be advertised in Sunday newspapers and aimed at older people. We’ve never got to the bottom of who the OEM was who manufactured them, or indeed cracked one apart to find the inevitable black epoxy blob processor. If we had to place a bet though, we’d guess there’s an 8051 core in there somewhere.

From Blog – Hackaday via this RSS feed

Although Nintendo is mostly famous for making great games, they also have an infamous reputation for being highly litigious not only for reasonable qualms like outright piracy of their games, but additionally for more gray areas like homebrew development on their platforms or posting gameplay videos online. With that sort of reputation it’s not surprising that they don’t release open-source drivers for their platforms, especially those like the Wii U with unique controllers that are difficult to emulate. This Wii U gamepad emulator seeks to bridge that gap.

The major issue with the Wii U compared to other Nintendo platforms like the SNES or GameCube is that the controller looks like a standalone console and behaves similarly as well, with its own built-in screen. Buying replacement controllers for this unusual device isn’t straightforward either; outside of Japan Nintendo did not offer an easy path for consumers to buy controllers. This software suite, called Vanilla, aims to allow other non-Nintendo hardware to bridge this gap, bringing in support for things like the Steam Deck, the Nintendo Switch, various Linux devices, or Android smartphones which all have the touch screens required for Wii U controllers. The only other hardware requirement is that the device must support 802.11n 5 GHz Wi-Fi.

Although the Wii U was somewhat of a flop commercially, it seems to be experiencing a bit of a resurgence among collectors, retro gaming enthusiasts, and homebrew gaming developers as well. Many games were incredibly well made and are still experiencing continued life on the Switch, and plenty of gamers are looking for the original experience on the Wii U instead. If you’ve somehow found yourself in the opposite position of owning of a Wii U controller but not the console, though, you can still get all the Wii U functionality back with this console modification.

Thanks to [Kat] for the tip!

From Blog – Hackaday via this RSS feed

A lot of projects we see around here are built not just because they can be built, but because there’s no other option available. Necessity is the mother of invention, as they say. And for [Jeff] who has many thousands of dollars of food stowed in a chest freezer, his need for something to keep track of his freezer’s status was greater than any commercial offering available. Not only are freezers hard on batteries, they’re hard on WiFi signals as well, so [Jeff] built his own temperature monitor to solve both of these issues.

The obvious solution here is to have a temperature probe that can be fished through the freezer in some way, allowing the microcontroller, battery, and wireless module to operate outside of the harsh environment. [Jeff] is using K-type thermocouples here, wired through the back of the freezer. This one also is built into a block of material which allows him to get more diffuse temperature readings than a standard probe would provide. He’s also solving some other problems with commercially available probes here as well, as many of them require an Internet connection or store data in a cloud. To make sure everything stays local, he’s tying this in to a Home Assistant setup which also allows him to easily make temperature calibrations as well as notify him if anything happens to the freezer.

Although the build is very robust (or, as [Jeff] himself argues, overengineered) he does note that since he built it there have been some additional products offered for sale that fit this niche application. But even so, we always appreciate the customized DIY solution that avoids things like proprietary software, subscriptions, or cloud services. We also appreciate freezers themselves; one of our favorites was this restoration of a freezer with a $700,000 price tag.

From Blog – Hackaday via this RSS feed

We all know UV radiation for its contributions to getting sunburned after a long day outside, but were you aware there are several types different types of UV rays at play? [Michael] has come up with a Flipper Zero add on board and app to measure these three types of radiation, and explained some of the nuances he learned about measuring UV along the way.

At the heart of this project is an AS7331 sensor, it can measure the UV-A, UV-B, and UV-C radiation values that the Flipper Zero reads via I2C. While first using this chip he realized to read these values is more complex than just querying the right register, and by the end of this project he’d written his own AS7331 library to help retrieve these values. There was also a some experimenting with different GUI designs for the app, the Flipper Zero screen is only 128x64px and he had a lot of data to display. One feature we really enjoyed was the addition of the wiring guide to the app, if you install this Flipper Zero app and have just the AS7331 sensor on hand you’ll know how to hook it up. However if you want he also has provided the design files for a PCB that just plugs into the top of the Flipper Zero.

Head over to his site to check out all the details of this Flipper Zero project, and to learn more about the different types of UV radiation. Also be sure to let us know about any of your Flipper Zero projects.

From Blog – Hackaday via this RSS feed

Fabrication of uranium-based components via DLP. (Zanini et al., Advanced Functional Materials, 2024)

Within the nuclear sciences, including fuel production and nuclear medicine (radiopharmaceuticals), often specific isotopes have to be produced as efficiently as possible, or allow for the formation of (gaseous) fission products and improved cooling without compromising the fuel. Here having the target material possess an optimized 3D shape to increase surface area and safely expel gases during nuclear fission can be hugely beneficial, but producing these shapes in an efficient way is complicated. Here using photopolymer-based stereolithography (SLA) as  recently demonstrated by [Alice Zanini] et al. with a research article in Advanced Functional Materials provides an interesting new method to accomplish these goals.

In what is essentially the same as what a hobbyist resin-based SLA printer does, the photopolymer here is composed of uranyl ions as the photoactive component along with carbon precursors, creating solid uranium dicarbide (UC2) structures upon exposure to UV light with subsequent sintering. Uranium-carbide is one of the alternatives being considered for today’s uranium ceramic fuels in fission reactors, with this method possibly providing a reasonable manufacturing method.

Uranium carbide is also used as one of the target materials in ISOL (isotope separation on-line) facilities like CERN’s ISOLDE, where having precise control over the molecular structure of the target could optimize isotope production. Ideally equivalent photocatalysts to uranyl can be found to create other optimized targets made of other isotopes as well, but as a demonstration of how SLA (DLP or otherwise) stands to transform the nuclear sciences and industries.

From Blog – Hackaday via this RSS feed

Theoretically bicycle rental services are a great thing, as they give anyone the means to travel around comfortably without immediately having to rent a car, hail a taxi or brave whatever the local public transport options may be. That is until said services go out of business and suddenly thousands of increasingly more proprietary and locked-down e-bikes suddenly are at risk of becoming e-waste. So too with a recent acquisition by [Berm Peak] over at YouTube, featuring a ‘Gotcha’ e-bike by Bolt Mobility, which went AWOL back in 2022, leaving behind thousands of these e-bikes.

So how hard could it be to take one of these proprietary e-bikes and turn it into a run-off-the-mill e-bike for daily use? As it turns out, very hard. While getting the (36V) battery released and recharged was easy enough, the challenge came with the rest of the electronics, with a veritable explosion of wiring, the Tongsheng controller module and the ‘Gotcha’ computer module that locks it all down. While one could rip this all out and replace it, that would make the cost-effectiveness of getting one of these go down the drain.

Sadly, reverse-engineering the existing system proved to be too much of a hassle, so a new controller was installed along with a bunch of hacks to make the lights and new controller work. Still, for $75 for the bike, installing new electronics may be worth it, assuming you can find replacement parts and got some spare hours (or weeks) to spend on rebuilding it. The bike in the video costed less than $200 in total with new parts, albeit with the cheapest controller, but maybe jailbreaking the original controller could knock that down.

From Blog – Hackaday via this RSS feed

Some hacks are so great that when you die you receive the rare honor of both an obituary in the New York Times and an in memoriam article at Hackaday.

The recently deceased, Ed Smylie, was a NASA engineer leading the effort to save the crew of Apollo 13 with a makeshift gas conduit made from plastic bags and duct tape back in the year 1970. Ed died recently, on April 21, in Crossville, Tennessee, at the age of 95.

This particular hack, another in the long and storied history of duct tape, literally required putting a square peg in a round hole. After an explosion on the Apollo 13 command module the astronauts needed to escape on the lunar excursion module. But the lunar module was only designed to support two people, not three.

The problem was that there was only enough lithium hydroxide onboard the lunar module to filter the air for two people. The astronauts could salvage lithium hydroxide canisters from the command module, but those canisters were square, whereas the canisters for the lunar module were round. Ed and his team famously designed the required adapter from a small inventory of materials available on the space craft. This celebrated story has been told many times, including in the 1995 film, Apollo 13.

Thank you, Ed, for one of the greatest hacks of all time. May you rest in peace.

Header: Gas conduit adapter designed by Ed Smylie, NASA, Public domain.

From Blog – Hackaday via this RSS feed

Nothing caps off a great project like a good, professional-looking front panel. Looking good isn’t easy, but luckily [Accidental Science] has a tutorial for a quick-and-easy front panel technique in the video below.

It starts with regular paper, and an inkjet or laser printer to print your design. The paper then gets coated on both sides: matte varnish on the front, and white spray paint on the back. Then it’s just a matter of cutting the decal from the paper, and it gluing to your panel. ([Accidental Science] suggests two-part epoxy, but cautions you make sure it does not react to the paint.)

He uses aluminum in this example, but there’s no reason you could not choose a different substrate. Once the paper is adhered to the panel, another coat of varnish is applied to protect it. Alternatively, clear epoxy can be used as glue and varnish. The finish produced is very professional, and holds up to drilling and filing the holes in the panel.

We’d probably want to protect the edges by mounting this panel in a frame, but otherwise would be proud to put such a panel on a project that required it. We covered a similar technique before, but it required a laminator.If you’re looking for alternatives, Hackaday community had a lot of ideas on how to make a panel, but if you have a method you’ve documented, feel free to put in the tip line.

From Blog – Hackaday via this RSS feed

The video (embedded below) by [TechAltar] is titled “1 Month without US tech giants“, but it could have been titled “1 Month with Open Source Tools” — because, as it turns out, once you get out of the ecosystem set up by the US tech giants, you’re into the world of open source software (OSS) whether you want to be or not.

From a (German-made) Tuxedo laptop running their own Linux distro to a Fairphone with e/OS (which is French), an open version of Android, [TechAlter] is very keen to point out whenever Europeans are involved, which is how we learned that KDE has a physical headquarters, and that it’s in Berlin. Who knew?

He also gives his experiences with NextCloud (also German), can be used as an OSS alternative Google Workspaces that we’ve written about before, but then admits that he was the sole user on his instance. To which one must question: if you’re the sole user, why do you need a cloud-based collaborative environment? To try it out before getting collaborators involved, presumably.

Regardless what you think of the politics motivating this video, it’s great to see open source getting greater traction. While [TechAltar] was looking for European alternatives, part of the glory of open source is that it doesn’t matter where you’re from, you can still contribute. (Unless you’re Russian.) Have you found yourself using more open source software (or hardware) of late? Do you think the current political climate could lead to a broadening of its reach? Is this the year of the linux desktop? Let us know what you think in the comments.

From Blog – Hackaday via this RSS feed

Here’s something fun. Our hacker [Willow Cunningham] has sent us a copy of his homework. This is his final project for the “ECE 574: Cluster Computing” course at the University of Maine, Orono.

It was enjoyable going through the process of having a good look at everything in this project. The project is a “cluster” of 5x Raspberry Pi Pico microcontrollers — with one head node as the leader and four compute nodes that work on tasks. The software for the both nodes is written in C. The head node is connected to a workstation via USB 1.1 allowing the system to be controlled with a Python script.

The cluster is configured to process an embarrassingly parallel image convolution. The input image is copied into the head node via USB which then divvies it up and distributes it to n compute nodes via I2C, one node at a time. Results are given for n = {1,2,4} compute nodes.

It turns out that the work of distributing the data dwarfs the compute by three orders of magnitude. The result is that the whole system gets slower the more nodes we add. But we’re not going to hold that against anyone. This was a fascinating investigation and we were impressed by [Willow]’s technical chops. This was a complicated project with diverse hardware and software challenges and he’s done a great job making it all work and in the best scientific tradition.

It was fun reading his journal in which he chronicled his progress and frustrations during the project. His final report in IEEE format was created using LaTeX and Overleaf, at only six pages it is an easy and interesting read.

For anyone interested in cluster tech be sure to check out the 256-core RISC-V megacluster and a RISC-V supercluster for very low cost.

From Blog – Hackaday via this RSS feed

If you’ve ever squinted at a DE10-Nano wondering where the fun part begins, you’re not alone. This review of the Mr. MultiSystem 2 by [Lee] lifts the veil on a surprisingly noob-friendly FPGA console that finally gets the MiSTer experience out of the tinker cave and into the living room. Developed by Heber, the same UK wizards behind the original MultiSystem, this follow-up console dares to blend flexibility with simplicity. No stack required.

It comes in two varieties, to be precise: with, or without analog ports. The analog edition features a 10-layer PCB with both HDMI and native RGB out, Meanwell PSU support, internal USB headers, and even space for an OLED or NFC reader. The latter can be used to “load” physical cards cartridge-style, which is just ridiculously charming. Even the 3D-printed enclosure is open-source and customisable – drill it, print it, or just colour it neon green. And for once, you don’t need to be a soldering wizard to use the thing. The FPGA is integrated in the mainboard. No RAM modules, no USB hub spaghetti. Just add some ROMs (legally, of course), and you’re off.

Despite its plug-and-play aspirations, there are some quirks – for example, the usual display inconsistencies and that eternal jungle of controller mappings. But hey, if that’s the price for versatility, it’s one you’d gladly pay. And if you ever get stuck, the MiSTer crowd will eat your question and spit out 12 solutions. It remains 100% compatible with the MiSTer software, but allows some additional future features, should developers wish to support them.

Want to learn more? This could be your entrance to the MiSTer scene without having to first earn a master’s in embedded systems. Will this become an alternative to the Taki Udon announced Playstation inspired all-in-one FPGA console, which does require a DE-10 (or compatible)? Check the video here and let us know in the comments.

From Blog – Hackaday via this RSS feed

[ProjectsInFlight] has been on a mission to make his own semiconductors for about a year now, and recently shared a major step toward that goal: homemade spin-on dopants. Doping semiconductors has traditionally been extremely expensive, requiring either ion-implantation equipment or specialized chemicals for thermal diffusion. [ProjectsInFlight] wanted to use thermal diffusion doping, but first had to formulate a cheaper dopant.

Thermal diffusion doping involves placing a source of dopant atoms (phosphorus or boron in this case) on top of the chip to be doped, heating the chip, and letting the dopant atoms diffuse into the silicon. [ProjectsInFlight] used spin-on glass doping, in which an even layer of precursor chemicals is spin-coated onto the chip. Upon heating, the precursors decompose to leave behind a protective film of glass containing the dopant atoms, which diffuse out of the glass and into the silicon.

After trying a few methods to create a glass layer, [ProjectsInFlight] settled on a composition based on tetraethyl orthosilicate, which we’ve seen used before to create synthetic opals. After finding this method, all he had to do was find the optimal reaction time, heating, pH, and reactant proportions. Several months of experimentation later, he had a working solution.

After some testing, he found that he could bring silicon wafers from their original light doping to heavy doping. This is particularly impressive when you consider that his dopant is about two orders of magnitude cheaper than similar commercial products.

Of course, after doping, you still need to remove the glass layer with an oxide etchant, which we’ve covered before. If you prefer working with lasers, we’ve also seen those used for doping.

From Blog – Hackaday via this RSS feed

When we hear the words “pitot tube,” we tend to think more of airplanes than of air ducts, but [Franci Kopač]’s guide to pitot tubes for makers shows that they can be a remarkably versatile tool for measuring air speed, even in domestic settings.A pitot tube is a tube which faces into an air flow, with one hole at the front of the tube, and one on the side. It’s then possible to determine the air speed by measuring the pressure difference between the side opening and the end facing into the wind. At speeds, temperatures, and altitudes that a hacker’s likely to encounter (i.e. not on an airplane), the pressure difference is pretty small, and it’s only since the advent of MEMS pressure sensors that pitot tubes became practical for amateurs.[Franci]’s design is based on a Sensiron SDP differential pressure sensor, a 3D-printed pitot tube structure, some tubing, and the microcontroller of your choice. It’s important to position the tube well, so that it doesn’t experience airflow disturbances from other structures and faces straight into the air flow. Besides good positioning, the airspeed calculation requires you to know the air temperature and absolute pressure.[Franci] also describes a more exotic averaging pitot tube, a fairly simple variation which measures air speed in cavities more accurately. He notes that this provides a more inexpensive way of measuring air flow in ducts than air conditioning flow sensors, while being more resilient than propeller-based solutions – he himself used pitot tubes to balance air flow in his home’s ventilation. All of the necessary CAD files and Arduino code are available on his GitHub repository.If you’re looking for a more conventional duct flow meter, we’ve covered one before. We’ve even seen a teardown of a pitot tube sensor system from a military drone.

From Blog – Hackaday via this RSS feed

We love Arduino here at Hackaday; they’ve probably done more to make embedded programming accessible to more people than anything else in the history of the field. One thing the Arduino ecosystem is rarely praised for is its speed. That’s where [Playduino]  comes in, with his video (embedded below) that promises to make everyone’s favourite microcontroller run 50x faster.

You might be expecting an unstable overclocking setup, with swapped crystals, tweaked voltages and a hefty heat sink, but no! This is stock hardware. The 50x speedup comes from one simple hack: don’t use digitalWrite();

If you aren’t familiar, the digitalWrite() function is one of the key functions Arduino gives you to operate its boards– specify the pin and the value (high or low) to drive it. It’s very easy, but it’s also very slow. [Playduino] takes a moment to show just how much is going on under the hood when you call digitalWrite(), and shows you what you can do instead if you have a need for speed. (Hint: there’s no Arduino-provided code involved; hardware registers and the __asm keyword show up.)

If you learned embedded programming in an earlier era, this will probably seem glaringly obvious. If you, like so many of us, got started inside of the Arduino ecosystem, these closer-to-the-metal programming techniques could prove useful tools in your quiver. Big thanks to [Stephan Walters] for the tip.

Of course if you prefer to speed things up by hardware rather than software, you can overclock an Arduino– with liquid nitrogen, even.

From Blog – Hackaday via this RSS feed

Almost all satellites have some kind of thrusters aboard, but they tend to use them as little as possible to conserve chemical fuel. Reaction wheels are one way to make orientation adjustments without running the thrusters, and [Zachary Tong]’s liquid metal reaction wheel greatly simplifies the conventional design.

Reaction wheels are basically flywheels. When a spacecraft spins one, conservation of angular momentum means that the wheel applies an equal and opposite torque to the spacecraft, letting the spacecraft orient itself. The liquid-metal reaction wheel uses this same principle, but uses a loop of liquid metal instead of a wheel, and uses a magnetohydrodynamic drive to propel the metal around the loop.

[Zach] built two reaction wheels using Galinstan as their liquid metal, which avoided the toxicity of a more obvious liquid metal. Unfortunately, the oxide skin that Galinstan forms did make it harder to visualize the metal’s motion. He managed to get some good video, but a clearer test was their ability to produce torque. Both iterations produced a noticeable response when hung from a string and activated, and achieved somewhat better results when mounted on a 3D-printed air bearing.

Currently, efficiency is the main limitation of [Zach]’s motors: he estimates that the second model produced 6.2 milli-newton meters of torque, but at the cost of drawing 22 watts. The liquid metal is highly conductive, so the magnetohydrodynamic drive takes high current at low voltage, which is inconvenient for a spacecraft to supply. Nevertheless, considering how hard it is to create reliable, long-lasting reaction wheels the conventional way, the greatly improved resilience of liquid-metal reaction wheels might eventually be worthwhile.

If you’re curious for a deeper look at magnetohydrodynamic drives, we’ve covered them before. We’ve also seen [Zach]’s earlier experiments with Galinstan.

From Blog – Hackaday via this RSS feed

The two 128 kB EPROMs containing the special MacIntosh Plus ROM image. (Credit: Pierre Dandumont)

The Apple MacIntosh Plus was one of the most long-lived Apple computers and saw three revisions of its 128 kB-sized ROMs during its life time, at least officially. There’s a fourth ROM, sized 256 kB, that merges the Western ROMs with Japanese fonts. This would save a user of a Western MacIntosh Plus precious start-up time & RAM when starting software using these fonts. Unfortunately, this mythical ROM existed mostly as a kind of myth, until [Pierre Dandumont] uncovered one (machine-translated, French original).

Since this particular ROM was rumored to exist somewhere in the Japanese market, [Pierre] went hunting for Japanese MacIntosh Plus mainboards, hoping to find a board with this ROM. After finally getting lucky, the next task was to dump the two 128 kB EPROMs. An interesting sidenote here is that the MacIntosh Plus’ two ROM sockets use the typical programming voltage pin (Vpp) as an extra address line, enabling 256 kB of capacity across the two sockets.

This detail probably is why this special ROM wasn’t verified before, as people tried to dump them without using that extra address line, i.e. as a typical 27C512 64 kB EPROM instead of this proprietary pinout, which would have resulted in the same 64 kB dump as from a standard ROM. Thanks to [Doc TB]’s help and his UCA device it was possible to dump the whole image, with the images available for download.

Using this ROM image was the next interesting part, as [Pierre] initially didn’t have a system to test it with, and emulators assume the 128 kB ROM format. Fortunately these are all problems that can be solved, allowing the ROM images to be validated on real hardware as well as a modified MAME build. We were informed by [Pierre] that MAME releases will soon be getting support for this ROM as well.

Top image: Mainboard with the two 128 kB EPROMs containing the special MacIntosh Plus ROM image. (Credit: Pierre Dandumont)

From Blog – Hackaday via this RSS feed

Solder fumes are not nice on the lungs; nor are fumes from superglue, epoxy, or a whole mess of other things we often find ourselves using on the bench. Some people might be able to go the fume hood route to toss that all outside, but for the rest of us, there’s fume extractors. [Raph] has produced an extra-large, carbon-filtering, two-stage fume extractor that by all accounts really sucks — it is effective at hoovering up solder fumes up to 10″ from its inlet.

Note the 18V tool battery in the base. That’ll go for a bit.

Even better, [Raph] built a battery box for an 18 V cordless tool battery, and broke out banana plugs so this doubles as a variable power supply via a cheap LM2596 based DC-DC converter. It also serves as a speed controller for the fans, which makes us wonder if you can adjust the PSU output and the fan speed independently…

Maximum suckage is achieved through careful baffle design. Check out the blog to see the trial-and-error process at work. Of course, having a 200 mm axial fan and 140 mm blower fan front and rear is going to move some air no matter what. Which is required to get air flow through the 38 mm thick activated carbon filter that should scrub all nasties quite nicely. We aren’t filtration experts but we can agree with [Raph]’s estimate that it will last “a while”.

If you want to roll your own, all of the STEP files are on GitHub, and [Raph]’s blog has an excellent step-by-step build guide. We’ve seen other hacks from [Raph] before, from his dovetailed modular breadboard to the machine that shaped his bed and automation for his camper van.

From Blog – Hackaday via this RSS feed

Image by [dynam1keNL] via redditBut sir! I can’t believe I missed [dynam1keNL]’s initial flat offering from about a year ago, the mikefive, which came about when he and some friends ordered switches directly from Kailh and Kailh were like, do you want to try these even lower-profile PG1316 laptop switches? It’s called the mikefive because it’s 5 mm thick.

That’s okay, though, because now you’re caught up and I can talk about his latest keyboard, the mikecinq. The inspiration for this one includes the aesthetics of Le Chiffre and the slimness of Le Oeuf. As you’ll see in the gallery, the top is ever-so-slightly slanted downward from the top.

You can see it really well in the second picture — the top row is flush with the case, and the keys gradually get taller toward the thumb clusters. All [dynam1keNL] really had to do was 3D model the new case and screw in the PCB from his daily driver mikefive.

Image by [dynam1keNL] via reddit[dynam1keNL] ultimately found it nice and comfy, especially for the thumbs, but decided to take it one step further and designed a new switch footprint. Why? The PG1316s are surface-mount with contacts below the switch, so you really need a hotplate or oven to mount them.

So in order to deal with this, he made a dedicated mikecinq PCB with big cutouts with castellated holes beneath each switch. Now, the switch contacts are accessible from underneath and can be soldered with an iron.

You may have noticed that the mikefive production files are not available on GitHub — that’s because it was recently licensed and will be available soon. But if you want production files for the mikecinq, let him know in the comments.

Cyberpunk 2077 Here In 2025

Image by [felipeparaizo] via redditWhile this Cyberpunk 2077 keyboard is certainly nice enough to be a centerfold, [felipeparaizo] has a full write-up on GitHub, so here I go talking about it at length instead!

This here is a Sofle RGB v2.1 that, as we’ve concluded, is heavily inspired by Cyberpunk 2077. The case is 3D-printed and then airbrushed, and then stickered up with custom decals that include references to Arasaka and Samurai. The acrylic base lets even more Baja Blast-colored RGB goodness shine through.

The switches are Akko Crystal Blues, which seem like a great choice, and the caps are two combined sets — one matte and one translucent. This is the second version of the project, and you can see how the first one turned out over on GitHub.

via reddit

The Centerfold: An Avalanche of Color

Image by [CaptLynx] via redditSo this right here is an Avalanche keyboard, but at 60%. Go admire the original ones real quick; I’ll wait. They’re just as lovely as this one! I love the jawbreaker-esque layers of the case, and those knobs are exquisite.

Do you rock a sweet set of peripherals on a screamin’ desk pad? Send me a picture along with your handle and all the gory details, and you could be featured here!

Historical Clackers: the Brackelsberg

The Classic Typewriter page calls the Brackelsberg syllabic typewriter “another hallucinogenic creation from the golden age of writing machine design“, and I don’t disagree.

Image via The Classic Typewriter Page

This 1897 machine had types arranged on several type sectors which swung up and down. Each sector carried about 30 types, which I take to mean characters.

The 132-key board was divided into four sectors, and they could be operated simultaneously — as in, you could type four characters at once, entering entire syllables if you so desired. Thus, it was called a syllabic typewriter.

A hammer struck from the rear, connecting the paper and ribbon with the types. It seems slow and cumbersome, doesn’t it? But Brackelsberg insisted that it was quiet, pointed out that the writing was always visible, and argued that the syllabic gimmick would make it fast and convenient to use.

Although never mass-produced, a working prototype was built and is pictured here in a photograph from Friedrich Muller’s book called Schriebmaschinen und Schriften-Vervielfältigung published in 1900.

Finally, a Keyboard That Looks Like a Typewriter and Might Not Suck

I say this because of the disappointment I suffered buying a similar Bluetooth keyboard for ten bucks from a place where everything typically costs half of that or less.  The thing just stopped working one day not long after the store warranty had expired. You win some, you lose some, I suppose.

The Yunzii QL75 typewriter keyboard. Image via Yunzii

Anyway, the Yunzii QL75 ought to fare better given that it’s ten times the cost to pre-order; at least I hope it does. And much like the crappy one I have, it comes in pink.

You can choose either Onyx tactile switches or Cocoa Cream V2 linear switches. But if you don’t like those, the switches are hot-swappable and compatible with 3-pin and 5-pins both.

The keycaps are ABS with a matte chrome electroplated finish and laser-engraved legends. Yes there is RGB, but it doesn’t shine through the keycaps, more like between them, it sounds like.

Thankfully, the QL75 works with QMK and VIA if you want to change things up. This thing has three-way connectivity to the device of your choice, which, if it’s small enough, can sit right above the keyboard where the paper would go.

There’s no telling what the knobs on the sides do, if anything, although there are arrows. On mine, they raise and lower the little kickstands.

Via TweakTown

Got a hot tip that has like, anything to do with keyboards? [Help me out by sending in a link or two](mailto:tips@hackaday.com?Subject=[Keebin' with Kristina]). Don’t want all the Hackaday scribes to see it? Feel free to [email me directly](mailto:kristinapanos@hackaday.com?Subject=[Keebin' Fodder]).

From Blog – Hackaday via this RSS feed

Saw what you want about the wisdom of keeping a 50-year-old space mission going, but the dozen or so people still tasked with keeping the Voyager mission running are some major studs. That’s our conclusion anyway, after reading about the latest heroics that revived a set of thrusters on Voyager 1 that had been offline for over twenty years. The engineering aspects of this feat are interesting enough, but we’re more interested in the social engineering aspects of this exploit, which The Register goes into a bit. First of all, even though both Voyagers are long past their best-by dates, they are our only interstellar assets, and likely will be for centuries to come, or perhaps forever. Sure, the rigors of space travel and the ravages of time have slowly chipped away at what these machines can so, but while they’re still operating, they’re irreplaceable assets.

That makes the fix to the thruster problem all the more ballsy, since the Voyager team couldn’t be 100% sure about the status of the primary thrusters, which were shut down back in 2004. They thought it might have been that the fuel line heaters were still good, but if they actually had gone bad, trying to switch the primary thrusters back on with frozen fuel lines could have resulted in an explosion when Voyager tried to fire them, likely ending in a loss of the spacecraft. So the decision to try this had to be a difficult one, to say the least. Add in an impending shutdown of the only DSN antenna capable of communicating with the spacecraft and a two-day communications round trip, and the pressure must have been unbearable. But they did it, and Voyager successfully navigated yet another crisis. But what we’re especially excited about is discovering a 2023 documentary about the current Voyager mission team called “It’s Quieter in the Twilight.” We know what we’ll be watching this weekend.

Speaking of space exploration, one thing you don’t want to do is send anything off into space bearing Earth microbes. That would be a Very Bad Thing, especially for missions designed to look for life anywhere else but here. But, it turns out that just building spacecraft in cleanrooms might not be enough, with the discovery of 26 novel species of bacteria growing in the cleanroom used to assemble a Mars lander. The mission in question was Phoenix, which landed on Mars in 2008 to learn more about the planet’s water. In 2007, while the lander was in the Payload Hazardous Servicing Facility at Kennedy Space Center, biosurveillance teams collected samples from the cleanroom floor. Apparently, it wasn’t very clean, with 215 bacterial strains isolated, 26 of which were novel. What’s more, genomic analysis of the new bugs suggests they have genes that make them especially tough, both in their resistance to decontamination efforts on Earth and in their ability to survive the rigors of life in space. We’re not really sure if these results say more about NASA’s cleanliness than they do about the selective pressure that an extreme environment like a cleanroom exerts on fast-growing organisms like bacteria. Either way, it doesn’t bode well for our planetary protection measures.

Closer to home but more terrifying is video from an earthquake in Myanmar that has to be seen to be believed. And even then, what’s happening in the video is hard to wrap your head around. It’s not your typical stuff-falling-off-the-shelf video; rather, the footage is from an outdoor security camera that shows the ground outside of a gate literally ripping apart during the 7.7 magnitude quake in March. The ground just past the fence settles a bit while moving away from the camera a little, but the real action is the linear motion — easily three meters in about two seconds. The motion leaves the gate and landscaping quivering but largely intact; sadly, the same can’t be said for a power pylon in the distance, which crumples as if it were made from toothpicks.

And finally, “Can it run DOOM?” has become a bit of a meme in our community, a benchmark against which hacking chops can be measured. If it has a microprocessor in it, chances are someone has tried to make it run the classic first-person shooter video game. We’ve covered dozens of these hacks before, everything from a diagnostic ultrasound machine to a custom keyboard keycap, while recent examples tend away from hardware ports to software platforms such as a PDF file, Microsoft Word, and even SQL. Honestly, we’ve lost count of the ways to DOOM, which is where Can It Run Doom? comes in handy. It lists all the unique platforms that hackers have tortured into playing the game, as well as links to source code and any relevant video proof of the exploit. Check it out the next time you get the urge to port DOOM to something cool; you wouldn’t want to go through all the work to find out it’s already been done, would you?

From Blog – Hackaday via this RSS feed

An intriguing mouth-played instrument emerged—and won—at the 2023 Guthman Musical Instrument Contest hosted by Georgia Tech. [Keith Baxter] took notice and reproduced the idea for others to explore. The result is the Zen Flute Mouth Theremin, a hybrid of acoustics, electronics, and expressive performance.

At its core lies a forced Helmholtz resonator, a feedback system built with a simple microphone and speaker setup. The resonator itself? The user’s mouth. The resulting pitch, shaped by subtle jaw and tongue movements, is detected and used to drive a MIDI controller feeding an external synthesizer.

Like a trombone or classic electromagnetic theremin, the Zen Flute doesn’t rely on discrete notes. Instead, the pitch is bent manually to the desired frequency. That’s great for expression, but traditional MIDI quantisation can map those “in-between” notes to unexpected semitones. The solution? MIDI Polyphonic Expression (MPE). This newer MIDI extension allows smooth pitch transitions and nuanced control, giving the Zen Flute its expressive character without the hiccups.

Physically, it’s an elegant build. A flat speaker and microphone sit side-by-side at the mouth end, acoustically isolated with a custom silicone insert. This assembly connects to a length of clear PVC pipe, flared slightly to resemble a wind instrument. Inside, a custom PCB (schematic here) hosts a mic preamp, an audio power amp, and a Teensy 4.1. The Teensy handles everything: sampling the mic input, generating a 90-degree phase shift, and feeding it back to the speaker to maintain resonance. It also detects the resonant frequency and translates it to MPE over USB.  A push-button triggers note onset, while a joystick adjusts timbre and selects modes. Different instrument profiles can be pre-programmed and toggled with a joystick click, each mapped to separate MIDI channels.

Mouth-controlled instruments are a fascinating corner of experimental interfaces. They remind us of this Hackaday Prize entry from 2018, this wind-MIDI hybrid controller, and, of course, a classic final project from the Cornell ECE4760 course, a four-voice theremin controlled by IR sensors.

From Blog – Hackaday via this RSS feed

Shade is the mortal enemy of solar panels; even a little shade can cause a disproportionate drop in power output. [Alex Beale] reviewed a “revolutionary” shade-tolerant panel by Renology in a video embedded below. The results are fascinating.

While shading large portions of the panels using cardboard to cut off rows of cells, or columns of cells, the shade tolerant panel does very well compared to the standard panel– but when natural, uneven shading is applied to the panel, very little difference is seen between the standard and active panels in [Alex]’s test.  We suspect there must be some active components to keep power flowing around shaded cells in the Renology panel, allowing it to perform well in the cardboard tests. When the whole panel is partially shaded, there’s no routing around it, and it performs normally.

It’s hard to see a real-world case that would justify the extra cost, since most shading doesn’t come with perfect straight-line cutoffs. Especially considering the added cost for this “shade tolerant” technology (roughly double normal panels).

You might see a better boost by cooling your solar panels. Of course you can’t forget to optimize the output with MPPT. It’s possible that a better MPPT setup might have let the Renology panel shine in this video, but we’re not certain. Whatever panels you’re using, though, don’t forget to keep them clean.

From Blog – Hackaday via this RSS feed

We love clocks, but we especially love unusual timepieces that aren’t just about showing the hour of the day. [Simone Giertz] built a flip clock moon phase tracker for a friend.

While in Egypt for Cairo Maker Faire, [Giertz] and [dina Amin] found some old flip clocks at a flea market and had to have them. [Amin] mentioned wanting to make a moon phase tracker with one, and [Giertz] decided to try her hand at making her own version. A side quest in more comfortable flying is included with the price of admission, but the real focus is the process of figuring out how to replicate the flip clocks original mechanism in a different size and shape.

[Giertz] cut out 30 semi-circle flaps from polystyrene and then affixed vinyl cut-outs to the flaps. The instructions for the assembly suggest that this might not be the best way to do it, and that printing stickers to affix to the flaps might work better since the cut vinyl turned out pretty fiddly. We really like the part where she built a grid jig to determine the optimal placement of the beams to keep the flaps in the right position after a disheartening amount of difficulties doing it in a more manual way. Her approach of letting it rest for twenty minutes before coming back to it is something you might find helpful in your own projects.

Best of all, if you want to build your own, the files are available for the flip moon station on the Yetch website. You’ll have to come up with your own method to drive it though as that isn’t in the files from what we saw.

From Blog – Hackaday via this RSS feed

The hack we have for you today is among our most favorite types of hack: a good, honest, simple, and well documented implementation that meets a real need. Our hacker [Solo Pilot] has sent in a link to their basement monitor.

The documentation is quite good. It’s terse but comprehensive with links to related information. It covers the background, requirements, hardware design, sensors, email and SMS alerts, software details, and even has some credits at the end.

Implementing this project would be a good activity for someone who has already made an LED flash and wants to take their skills to the next level by sourcing and assembling the hardware and then configuring, compiling, deploying, and testing the software for this real-world project.

To make this project work you will need to know your way around the Arduino IDE in order to build the software from the src.zip file included with the documentation (hint: extract the files from src.zip into a directory called AHT20_BMP280 before opening AHT20_BMP280.ino and make sure you add necessary boards and libraries).

One feature of the basement monitor that we would like to see is a periodic “everything’s okay” signal from the device, just so we can confirm that the reason we’re not getting an alarm about flooding in the basement is because there is no flood, and not because the battery ran dead or the WiFi went offline.

If you’ve recently started on your journey into where electronics meets software a project such as this one is a really great place to go next. And of course once you are proficient with the ESP8266 there are a thousand such projects here at Hackaday that you can cut your teeth on. Such as this clock and this fault injection device.

From Blog – Hackaday via this RSS feed