Mysterious Files PH

Throughout the centuries the art of lock-making and lock-picking have been trapped in a constant struggle, with basic lock designs being replaced by ever more complex ones that seek to thwart any lockpicking attempts, as well as less gentle approaches. When it comes to the very common pin-and-tumbler lock design, the main issue here is that the keyway also provides direct access to the lock’s mechanism. This led [Works By Design] to brainstorm a lock design in which the keyway is hidden.

The ingenious part here is that because the actual key is rotated away after insertion, there is no clear path to the pins. This did require some creative thinking to have a somewhat traditional style key as well as a way to turn the internal mechanism so that the key would be pressed against the pins. Here inspiration was drawn from the switchable magnet mechanism as seen with e.g. magnetic bases. This ensures the key and key handle can be detached and attached quite firmly.

After many 3D printed prototypes, a metal version was CNCed and subjected to some early testing by a locksmith, who even with having seen the CAD model of the lock was stumped. With this initial result and some user feedback in the bag, it was time for large-scale testing with more lockpick enthusiasts, as there are many more ways to open a lock beyond pushing pins. That said, a mechanism was also added to the lock to prevent bumping attacks.

The next testers were found in the Lock Pickers United community, one of whom raised the issue of an impressioning attack. With a couple of test locks on their way to said lockpicking enthusiasts it’ll be exciting to see whether this new lock design will set the standard for future locks or not.

Perhaps at this point, getting NetBSD running on an obscure piece of hardware is a dog-bites-man story, and not worth reporting– their motto, after all, is “Of course it runs NetBSD”. So, the fact that [RetroComputingRanch] has got NetBSD running on a vintage Chyron Maxine broadcast computer is perhaps remarkable only for the fact that few people have even heard of Chyron before.

He’s already done a series of videos in which they explore this odd, old computer, which is powered by a Motorola 68040 on a VME bus and was once used to generate digital overlays– text and the like– on broadcast TV. NetBSD does have a port for the Motorolla VME SBCs, so he was able to vibe it onto the specific vme168 board that the Chyron is based on. It happens off screen, but apparently it was AI agent work that went into condensing the documentation for this machine as well as getting the NetBSD port set up. That’s a bit ironic, since NetBSD would never allow that in its commits. 

Again, the Chyron Maxine was never intended to be a general-purpose-computer, and certainly never intended to run UNIX– it was meant to overlay text onto TV signals. With 4 MB of RAM, NetBSD leaves very little free once booted in single-user mode, but he realized that with a few extra chips the proprietary RAM board could become an 8 MB module. It seems like a pittance nowadays, but anyone who’s played with classic UNIX knows you can do a lot in 8 MB– even if only about 3MB is ‘free’ according to TOP.

There’s work still to be done– right now, it boots, but he wants to use NetBSD to really own this machine, so that’ll mean getting the vintage video hardware set up. Last time we saw a NetBSD user, they were doing game dev on a G4 Macbook, but nothing will ever match the legendary NetBSD toaster– not even toaster-shaped callbacks.

One of the more interesting categories of our ongoing Green Power Challenge is “anything but PV” — and since the radiated power of Near Field Communication is decidedly not photovoltaic, this hack by [caspar] to control a Pi Pico W from his phone using a tuned antenna absolutely counts.

Now, of course you’re not going to power the whole microcontroller that way, but [caspar] figures you don’t need to: the MCU is hooked to a battery, but through a transistor. That means it’s not asleep, but fully un-powered: only the leakage current of the transistor is draining that battery, so it can last a very long time. The waking is handled with a tuned NFC antenna hooked to a ST25DV04KC NFC chip. This chip is designed to be powered via NFC, and of course to accept commands. The ST25 then wakes the Pico — one GIPO on the MCU is used to latch that power transistor ON — and passes on the command via I2C.

Our favorite part might be the script he put on the Pico to live-tune the antenna coil, which you can see demoed in a video below, along with simplest possible demonstration of starting blinky on the Pico from the phone.

You aren’t limited to just a Pico and a blinky LED as in his proof-of-concept demo: [caspar] also uses the same technique with an e-ink display, which is pretty similar to the e-ink price tags you’ve likely seen at the grocery store, without the joy of reverse engineering.

Also without batteries, which is pretty neat, and arguably pretty green. If you’ve been hacking away at something that uses alternative energy, this challenge is still open — just get your project onto Hackaday.io and submitted by April 27.

You’re probably not going to hang out around Chernobyl any time soon. Still, knowing the conditions there can both satisfy your curiosity and provide scientific value. To that end, [Yury Ilyin] has spent the last couple decades installing homebrew weather stations across the Exclusion Zone for his own interest. 

The remote weather stations that [Yury] builds all follow a similar design. Each runs on three 18650 lithium cells, charged via a small solar panel. Most of these cells were salvaged from old laptop battery packs. These cells are used to power a GPRS or WiFi communications module, along with a temperature, humidity, and pressure sensor, and a Geiger counter, because, well… it’s Chernobyl.

He has been lucky enough to keep costs down by finding an old generation GPRS SIM card that could be cloned and used across multiple devices, and thus far has had no trouble receiving signals from his many distributed stations. He’s been able to use his sensor network to track the gradual decline of radioactive emissions in the area from Cs-137, as well as keep an eye on the local weather conditions in an area few ever tread.

[Yury] has built over two dozen of these devices, and several have passed the test of time—with the lithium cells and cellular hardware surviving both high and freezing temperatures as well as the ravages of rain and time. He’s continued to refine the design over the years, starting out with an ATmega644 running the show, and later upgrading to STM32 microcontrollers.

We’ve explored distributed radiation sensor networks before, too, as well as many a remote weather station.

Thanks to [Luc Van Braekel] and [Paulo Ramos] for the tip!

Most makers find themselves in need of a benchtop power supply at some point or another. Basic models can be had relatively cheaply, but as your current demands go higher, so does the price. [Danilo Larizza] has figured out an alternative solution—repurposing old server hardware to do the job instead.

The build is based around an HP Common Slot (CS) server power supply. They can be readily had for well under $50 if you know where to look. Even better, they can deliver over 50 amps at 12 volts, which happens to be a very useful voltage indeed. All you need to do is some minor mods.

A jumper on a couple of pins will get the power supply running, and with the addition of some terminals for your hook-up leads, you’re ready to go. As a hot-swappable single unit, the power supply is already outfitted with a ventilation fan to keep everything cool. If so desired, you can even make some further mods to bump output voltage a little ways past 13 or 14 volts if you’d like to use them for certain battery charging tasks.

Sure, you’re not getting a variable power supply, but if you need 12 volts and lots of it, this is a great way to go. We’ve featured similar builds before, too, turning ATX PC power supplies into useful benchtop tools.

We’ll start things off this week with a story that’s developing more than 25 billion kilometers from Earth — on Friday, NASA announced that the command had been sent to shut down Voyager 1’s Low-energy Charged Particles (LECP) instrument. As the power produced by the spacecraft’s aging radioisotope thermoelectric generator (RTG) continues to dwindle, engineers at the Jet Propulsion Laboratory have been systematically turning off various systems to extend the mission for as long as possible. It’s believed that deactivating LECP should buy them another year, during which engineers hope to implement a more ambitious power-saving routine. If this sounds a bit familiar, you’re probably thinking of Voyager 2. The plug was pulled on its LECP instrument back in March of 2025.

The JPL engineers hope that their new plan may allow them to reactivate previously disabled systems on the twin space probes, but even if everything goes according to plan, there’s no fighting the inevitable. At some point, there simply won’t be enough juice in the RTGs to keep the lights on. Although it’s going to be a sad day when we have to bring you that news, surviving a half-century in space is one hell of a run.

Speaking of ending a run, just a week after Amazon announced that pre-2012 Kindles would no longer be supported, the company is letting users know that the Kindle software for PCs will be discontinued in June. In its current form, at least. As Good e-Reader reports, Amazon is developing a new client for users who want to access the Kindle ecosystem from their computers, but it will only run on Windows 11. Since older software could be used to strip DRM from purchased ebooks, it seems likely this is another attempt to lock the platform down.

We’re not fans of arbitrary limits being placed on ebooks and the devices that read them, but on the other hand, there are definitely systems out there that could stand to be tightened up a bit. For example, research out of Quarkslab has shown that the electronic control unit (ECU) from a wrecked vehicle can reveal a surprising amount of information.

After picking up a used ECU, they were able to dump its NAND flash chip and decode the log files it contained. It turns out the car had GPS logs going back to the day it rolled off the assembly line, and the researchers were able to reconstruct every trip it ever made.

By cross-referencing the last recorded coordinates with social media posts, they were even able to find pictures of the crash that took the vehicle out of commission. It’s bad enough that personal information can be scraped off of secondhand hard drives; now we’ve got to worry about what happens to our cars after they get hauled off to the junkyard.

If these are the sort of stories that keep you on two wheels rather than four, you may be interested in the latest innovation from Škoda Auto. In an effort to reduce collisions with pedestrians, they’ve developed a bike bell that penetrates active noise cancellation (ANC) systems. The logic goes like this: if someone is walking around with headphones that feature ANC, they might not hear the bell of an approaching bike. So they teamed up with researchers from the University of Salford to essentially find the weaknesses in existing ANC systems.

As you might have guessed, irregular noises are harder to block out than constant tones. Researchers uncovered a gap between 750 and 780 Hz where sounds could sneak through. The mechanical bell uses both principles to defeat ANC, and in testing, it was shown to provide headphone-wearing pedestrians  more time to react to an approaching bicycle.

Finally, we’ll bring this week’s post full circle by starting and ending on a space story: earlier this week, PBS released the hour-long documentary Artemis II: Return to the Moon on YouTube. Watching PBS programming on YouTube might seem a bit odd, but that’s the world we live in these days. At any rate, the video is a fascinating look into what went into the recently concluded Moon mission and has us even more excited for Artemis III and beyond.

See something interesting that you think would be a good fit for our weekly Links column? Drop us a line, we’d love to hear about it.

Noise cancelling headphones are a great way to insulate yourself from the bustle of the city, but due to their power requirements, continuous use means frequent recharging. [Alessandro Sgarzi] has an elegant and unique solution — powering the noise cancelling electronics by harvesting energy from the ambient noise of the city via a sheet of piezoelectric film.

This impressive feat is achieved using a LTC3588-1 power harvesting IC and a pair of supercapacitors, while an STM32L011K4T6 microcontroller processes the input from a MEMS microphone and feeds a low-power class D amplifier. This circuit consumes an astounding 1.7 nW, a power that a noisy city is amply able to supply. Audio meanwhile comes via a traditional 3.5 mm connector, which we are told is the cool kids’ choice nowadays anyway.

We like this project, and since it’s part of our 2026 Green Powered Challenge, it’s very much in the spirit of the thing. You’ve just got time to get your own entry in, so get a move on!