Mysterious Files PH

Usually, when you want to make glitchy images with lots of colors and things, you have to poke around inside a camera and successfully circuit-bend the thing without bricking it. But [sharkbiscuit101] proves that this isn’t necessary, provided you have a Raspberry Pi 4 and a few other components.

Now we don’t have a lot of detail here, but [sharkbiscuit101] is being heavily encouraged to share the relevant files and a component list. What we do know is that the there’s a screen for previewing images, a portable battery, a shutter button, a rotary encoder to dial in the weirdness, and a game pad for controls. Using the script and a slider, you can tweak different aspects of the image to basically break it down in real time. If you find a nifty combination, you can use the rotary encoder to save and then recall presets.

If you’re wondering about the grip, that’s a Sharge battery from the Bezos Barn. Per [sharkbiscuit101], it is a good size, and since Pi 4 doesn’t have a power button, it can be turned on and off at the battery.

Of course, you can always mess with JPGs on a raw, textual level instead, or produce standard photographs with a pinhole camera.

Recently we featured an unusual Commodore 8-bit computer on the bench of [Tynemouth Software] — a Commodore 64 in a PET case. One of the unique parts it had was a board which took the composite output from the mainboard and split out the sync pulses for the monitor, and now they’re back to give it a full reverse engineer.

Perhaps the first surprise is why this board is necessary at all, after all one might expect an 8-bit machine to have those signals already at hand. It seems that the VIC chip inside the 64 did the combination to composite internally, so no such luck for the Commodore engineers. The board they designed then is a complete and very well-engineered sync splitter.

The technology of a video signal has its origins in the 1930s, so it’s not hard to extract both vertical and horizontal sync pulses with little more than a few passive components and a couple of transistors. The trouble with such a simple approach is that the output will work, but it will be messy and crucially, not have quite the required timing. The Commodore board uses the same approach as a simple discrete circuit of having a pair of filters with a time constant selected to catch the relevant sync, but extends it with extra logic. There are one-shots designed to provide clean pulses of exactly the right length, and gates that provide blanking to remove the chance of pulses ending up where they shouldn’t. The video path is the only part which might differ from a conventional sync splitter, because as the output from the 64 is all-digital, it takes a TTL-level through a gate rather than a more conventional analogue path.

You can see the rest of the machine in our original write-up, and we’re reminded that the boards haven’t been cleaned at their owner’s request, to preserve their patina.

In this episode, Hackaday Editors Elliot Williams and Tom Nardi start things off by discussing the latest reason that cheap PCB fabrication isn’t quite as cheap as it once was. The conversation will then move on to hacking electronic shelf labels, stylish e-ink status displays, cutting metal at home with high current and a bit of water, a solarpunk message board hiding in a IKEA-style lantern, and pushing NFC out of its comfort zone. From there you’ll hear about a matching transistors, taking pictures of the International Space Station, and Linux on the PS5. They’ll wrap up this week’s episode by going over the surprisingly simple concept behind flow batteries, and learn who’s still using leaded gasoline and why.

Check out the links if you want to follow along, and as always, tell us what you think about this episode in the comments!

Direct download in DRM-free MP3.

Episode 369 Show Notes:

News:

• You’ve Seen The Chip Shortage And The Memory Shortage, Now Prepare For The PCB Shortage
• The Zen Of Mechanical Keyboard Wiring
• Hackaday Europe: Last Round Of Speakers, Workshops

What’s that Sound?

• Think you know that sound? Fill out the form for a chance to win!

Interesting Hacks of the Week:

• TagTinker Lets You Hack Electronic Shelf Labels
  • Game Boy Vs. Electronic Shelf Labels
• E-paper Dashboard Reimagines Smart Home’s Connection With Technology
• Three-Axis Camera Slider From 3D Printer Parts
  • Camera Slider: Build Instead Of Buy Goes Awry
  • FluidNC Wiki Home Page
• Cutting Steel Gears With Homemade EDM
  • Powercore Aims To Bring The Power Of EDM To Any 3D Printer
• ESP32 Hosts SolarPunk Message Board
• Using NFC To Power Devices Instead Of Qi
  • ATtiny Chip Abused In RFID Application

Quick Hacks:

• Elliot’s Picks:
  • Matching Transistors
  • A Tool For Testing CANopen Networks
  • A Digital Audio Recorder For TOSLink
• Tom’s Picks:
  • Running Linux On The PS5 With A Hypervisor Exploit
  • A Shortwave Sensor To Monitor The Ionosphere
  • Photographing The ISS With A Thrift Store Lens Is Challenging

Can’t-Miss Articles:

• How Giant Tanks Of Fluid Could Help Support The Power Grid
  • A Vanadium Redox Flow Battery You Can Build
  • An Open Source Flow Battery
  • This Flow Battery Operates With No Pump Required
• Why Leaded Fuel Is Still A Thing

Rather than having users go through the inconvenience of having to punch in their current location, an increasing number of applications and websites use location services that can pin-point the current location of a user to within a certain number of meters or kilometers.

Unfortunately, [Evert Pot] found that with the demise of the Mozilla Location Service (MLS) in 2024, accuracy of the Linux Geoclue service had dropped to a resolution of about 25 km. Since a LAN tends to not move around a lot, this seemed like the perfect time to help Geoclue out with a local GPS server.

All that Geoclue looks for on the LAN is an mDNS service identifying as _nmea-0183._tcp that responds with the GPS coordinates as network packets containing an ASCII payload encoded using the NMEA 0183 standard. With this knowledge [Evert] was then able to quickly put together a Python-based server that simply blasts the static GPS coordinates of the LAN in question.

With the service running, Gnome Maps and Firefox with Google Maps both displayed the right location down to the house, as can be seen in the screenshots. With the same LAN service and a Mac system there was no such luck with Apple Maps unless Location Services was turned off, though presumably Apple uses its own equivalent to MLS.

The age of steam is long gone, but there are few railfans who don’t have a soft spot for the old rolling kettles. So you’d best believe when [AeroKoi] talks about 3D printed train whistles, that’s steam whistles. Generally speaking, Diesels have horns.

You would not expect printed plastic to hold up to live steam– but that’s why [AeroKoi] uses compressed air. Besides, it’s a lot easier to both justify and maintain an air compressor than a boiler in the shop. At least some hobbyists say it doesn’t make a huge difference with brass whistles, so it should be good enough for plastic. What’s interesting is that even with 120 PSI blasting through them, these multi-part prints held together and sounded amazing.

[AeroKoi] does demonstrate there was a learning curve to climb before he had a good whistle design, and shows you what features worked best. He shared two successes on Thingiverse: A 6-Chime whistle from the Sante Fe Railroad, and a Northern Pacific 5-chime whistle, both 4″ in diameter and printed in vertically sectioned parts. The Northern Pacific is not to be confused with the totally different Union Pacific Railroad, whose famous “Big Boy” also had a whistle feature in the video — though evidently he’s not as happy with it, since he did not share the design.

Those are all North American designs, but there’s no reason this technique wouldn’t work to replicate a more European sound; one of his early experiments was kind of going in that direction already. Of course if you want a perfect replica, the old ways are the best ways: cast brass and live steam. We’ve had a few articles about train whistles in the past, one of which was a doorbell. 

For this challenge, we asked you to show off your hacks that power themselves sustainably from the environment around them. After all, nobody likes wires, and changing batteries is just a hassle. What’s better than an autonomous gizmo? Nothing.

Because this is Hackaday, we expected to see some finished-looking projects, some absolutely zany concepts, and basically everything in-between, and you did not disappoint! So without further ado, let’s have a look at the 2026 Green Powered Challenge winners, each of whom will be going on a $150 shopping spree at DigiKey, our contest’s sponsor.

LightInk Solar Watch

LightInk is a beautiful wristwatch, and e-ink is a natural companion to the small power budget that you get with a wrist-mounted solar panel. But don’t be fooled by its good looks! The real beauty of this hack is the way that [Daniel Ansorregui] crammed the screen-updating routine into the wakeup stub in the RTC peripheral. This means that the ESP32 doesn’t have to access the SPI flash every time it wakes up, saving precious milliseconds of wake time, and cutting average power in half. This is a trick you’ll want to know even if you don’t need a sexy e-ink wristwatch. (Which you do.)

Supercapacitor Solar IoT

[Nelectra]’s “Heliotrax” solar supercapacitor charger stores up the sun’s power in low-maintenance supercapacitors until it’s time to wake up your device. But supercaps have an output voltage that depends dramatically on their state of charge, so [Nelectra] added a high-efficiency and low-leakage boost converter to get a nice constant voltage out. Depending on your current needs, it can charge up in the sun and run for a few dark days without any problems. It’s a one-stop shop for solar-powered IoT devices, and it should make a whole range of projects easier to realize.

powerTimer

[Juan Flores]’s powerTimer is another module that enables your small off-grid hacks. In this case, it’s a simple latching electronic switch, designed for ultra-low quiescent power. Maybe your project has a microcontroller with a good sleep mode, but the peripherals are leaky hogs? Put the powerTimer in the middle and get your whole system’s power budget down without much extra thought. And if you don’t want to wake the microcontroller, it’s got a low-power RTC on board that can handle periodic wakeups. It’s a sweet, simple design that solves a real problem, and our judges loved that.

Honorable Mentions

• Solar: We knew there would be some great solar-powered projects here, and [Jake Wachlin]’s Ultra Low Power Feather Development Board is a great example. He pairs a low-power accelerometer and barometer with a power-sipping microcontroller to almost achieve ambient-room-lighting capability. [Jake] says you have to put it directly under a light, or in indirect sunlight. But if you have full sun at your disposal, [Arnov Sharma]’s SolMate is a lovely DIY solar power bank that we’d love to bring to the park with us.
• Anything But PV: OK, enough solar. [Ethan]’s Gravity-Powered Digital Clock is exactly the sort of out-of-the-box idea we were hoping to see. He pairs a Casio F91W with an insane gear train, a homebrew electrical generator, and a dumbbell to gather up all of the gravity that makes it work. Or should do so. The gear train ended up having so many stages that it wouldn’t turn under its own magnified friction, and the project doesn’t quite spin. But we love the idea of a wind-up electrical clock, and we hope [Ethan] doesn’t give up!
• Least Power: [caspar]’s Harvesting NFC Energy to Transmit Commands includes a stock Pi Pico dev board and some AA batteries, so you might be thinking “where is the low power element?” It’s the NFC wakeup circuit that reads in some data and writes it directly to the Pico’s EEPROM, before it wakes the chip up, which then reads the command out of EEPROM and does whatever it does under normal battery power, and then shuts itself down again. We love the idea of surreptitious NFC-powered data insertion while the microcontroller is still sleeping.
• Most Power: We initially expected this honorable mention to go to an over-sized solar install, but in the end [alnwlsn]’s Practical Power Cycling won over our judges with an unbeatable display of human determination: over five years, [alnwlsn] has generated 38 kWh on his generator bike, has powered a 3D printer through a Benchy, and even toasted a piece of toast. Maybe the real power here is the human spirit? Check out [alnwlsn]’s great build logs and diary.

Thanks to All!

Much thanks to everyone who entered into this challenge. We had more great entries than we have space to feature, so be sure to check them all out on Hackaday.io. And of course, thanks again to DigiKey for sponsoring the contest, and for providing our three finalists with the parts they need!

A pinhole camera is almost a rite of passage in photography, given that you can make one so easily with little more than a cardboard box and enough tape to keep the light from coming through the cracks. [Socialmocracy] has made one that’s 3D printed, and it’s a nice design that takes 4″ by 5″ photographic paper. The shutter is held on with magnets, and the lid is attached with thumbscrews.

As neat as printed pinhole cameras are, it’s not as though they’re particularly uncommon. What makes this one stand out from the rest is that it’s actually two cameras in one. One box, two cameras, side by side. Landscape format and it’s a pair of panoramic cameras, while in portrait mode it’s a stereo camera. Even the simplest of cameras can do wigglegrams!

We like this camera, because it manages to add something to such a simple formula.. He’s taking comments on whether to release the STLs, so drop in your two cents.