TechyMagThings

Continuing on his quest to expose the dark underbelly of modern technology, [Benn Jordan] recently did a deep-dive into the rise of so-called robot dogs. Although their most striking resemblance with biological dogs is that they also have four legs and generally follow commands, [Benn] found many issues with them that range from safety issues due to limited sensory capabilities, to basic security vulnerabilities, all the way to suspicious network traffic from Unitree’s robot dog firmware.

Although not the only seller of this type of quadruped robot, Unitree Robotics has made a name for itself by offering very capable and yet very cheap products. Their basic quadruped robot costs only a few thousand clams and features Lidar and heaps of processing power, all of which should make it a pretty useful device.

Despite this, [Benn] found that the original task that he’d envisioned for the robot, as in protecting his chickens from uninvited visitors, wouldn’t quite work as the robot is rather blind. The reason for this is the placement of the Lidar below the head, which obscures most of what’s behind and around the robot. Rather than risk trampled chickens and chicks, this plan was thus abandoned.

When digging further into the robot, he found an easy to exploit arbitrary command execution flaw via the Wi-Fi password entry field, a year-old CVE-2025-2894 exploit, as well as highly suspicious traffic to Chinese servers whenever the robot’s software figured that it was not being watched.

Although much of this can be circumvented with hacks, issues like the sensory limitations and general distrust of firmware updates makes using these robots a rather daunting and often ill-advised proposition.

In the search for more exciting broken electronics to repair, [Hugh Jeffreys] bought a GoPro Hero 10 for US$100 with an apparently rather common issue of no camera input, along with a cracked display. This particular camera issue is rather obvious, with just darkness where the camera’s input should appear on the display. Since [Hugh] already needed a spare display, he figured that he might as well get an even more broken GoPro Hero 10 for parts.

Another US$40 later, [Hugh] found himself the proud owner of a second GoPro, this one being water damaged and no longer turning on. Getting to the internals requires removing the glued-in display, which is even trickier than with a smartphone. By inserting a thin blade, adding solvents and not prying, you can slowly work it loose.

With two disassembled GoPros it was now possible to swap modules. After a factory reset and firmware update had failed to fix the first GoPro, the camera module from the donor unit was inserted, but this made no difference. Amusingly, after cleaning the water-damaged unit’s PCBs, it was found to be in good working condition, so ultimately the second GoPro was repaired, leaving the ‘no camera input’ issue undiagnosed.

It’s possible that a board-level repair on the first unit can address the original issue, but without schematics this would likely entail a lot of blindly poking around, in the hope of finding a damaged MLCC or other obvious fault. There is also the possibility that this is a firmware issue, with some reporting luck mashing the report button, but others disagree.

Since [Hugh] did do the firmware reset and updating steps, and even inserted a whole new working camera module, it would seem to narrow the problem down to a board-level issue. Whatever the case may be, it’s a frustrating issue with a rather expensive device.

Aside from nostalgia, people claim to like CRTs because they’re apprehendable– the technology just makes more sense than the arcane wibbly-wobbly solid-state madness going on inside the driver chip of your new OLED. CRTs weren’t the first technology used to display moving images though, and their mechanical forebears were even easier to understand. For that reason we suppose it was only a matter of time before one of The Youths– in this case a British YouTuber by the name of [smill]–tried gaming on a mechanical television display.

The game in question was Minecraft— because of course it was, that’s the new generation’s DOOM–and the mechanical TV in question is not a priceless 1920s antique but a commercial kit that reproduces [John Logie Baird]s 1925 televisor. If you’re not familiar, it uses a flat disk– called a Nipkow disk after its inventor– with a series of holes in a spiral to demodulate a single lamp’s brightness variations into monochrome image made of scan-lines. As you might imagine, the resolution depends both on the size of the disk and its speed, so with a tabletop example you’re not going to get much– in this case, 32 holes for 32 lines. At least they’re not interlaced this time.

Getting a video signal from the computer to the LED in the televisor kit was the hard part of the hack. Aside from actually playing on the diminutive monochrome display, that is. There is a “video2NBTV” tool that can do the job, as the Narrow Band TV signal used by amateur radio enthusiasts still has the compatible timing values and modulation as what the televisor kit uses. We suspect that’s because the Televisor people used the modern NBTV standard as a starting point for their electronics, since [Baird]’s device reportedly ran 30 lines at only 5 frames per second, compared to the 32 lines at 15 FPS here.

Some of you may turn your nose up at this as a mere YouTube stunt, which is fair enough. At the same time, we cannot wait for the eventual arms race. Imagine when someone decides to go for 4K cred? Staring through a supersonic Nipkow disk makes pointing a particle accelerator at your face downright mundane. The kit [smill] used was monochrome, but if you want to repeat his antics in glorious colour, you can 3D print your own TV.

In the time Hackaday has been in existence we must have brought you plenty of projects housed in Altoids tins, as well as a sizeable number of cyberdecks. But until today with [Exercising Ingenuity]’s build, we’ve never brought you a project that combines the two. It’s a fully functional computer that runs Linux, and with its Altoids tin enclosure, looks for all the world like a miniature clamshell laptop.

Hardware wise it’s a Pi Zero with a UPS PHAT and an SPI display, but perhaps it’s arguably the home-made keyboard that really sets it apart. There’s a full-size USB port as well, and a selection of GPIOs are broken out to a header. It wasn’t all plain sailing though, the Altoids hinges needed modifying to make it close, and he driver for the SPI screen required an older version of Raspberry Pi OS. We will forgive it those foibles.

It’s fair to say we’ve not seen anything quite like this, in that there have been plenty of tiny laptops but never one as integrated as this. There’s a demo video with details of the build, that we’ve placed below.

Between 2000 and 2002 the Fisher Price Pixter was sold to children as an educational handheld toy with a touch screen that enabled drawing and listening to music in addition to cartridge-based games and more. It was followed up by multiple new iterations of the system, but as an ecosystem didn’t last beyond 2007. This has left much of the system in obscurity, with people like [Dmitry] doing their best to reverse-engineer, dump and document what they can, such as recently for the entire range of Pixter devices and most of the games.

One of the reasons why [Dmitri] got interested in the second-generation Pixter Color originally was as a potential PalmOS porting target, which gives somewhat of an idea of how these devices were meant to be used.

With absolutely no remaining known official documentation on how to develop software for the hardware reverse-engineering posed somewhat of a challenge. Fortunately this was made somewhat easier by the Pixter Color using the ARM-based LH7541, but worse by just how much of a minimal ARM7 implementation the SoC is. This was meant to go into a cheap-ish kid’s toy after all.

Where things got wild was that the firmware implements a 16-bit stack-based virtual machine, possibly due to initially having selected a completely different SoC. From here things get even crazier with how audio output is implemented, with [Dmitry] descending into a long-winded rant on this and all the weird things encountered during reverse-engineering.

After the Color Pixter its Multimedia sibling with slightly better SoC was also reverse-engineered, as well as the Classic device that started it all. This particular device uses an 8-bit VM, but a black-blob 6502 processor, which is rather astounding for a 2000-era device, but then again it was meant to be a toy.

In addition to getting a lot of reverse-engineering woes off his chest, [Dmitri] also details how he reverse-engineered and dumped the cartridges, as well as writing emulators to ensure that the Pixter legacy will endure, for better or worse.

Top image: Pixter with opened case. (Credit: Raimond Spekking, Wikimedia)

You normally think of fiber optic as something used in network cables. However, scientists employ dedicated fibers to detect earthquakes. In simple terms, they fire a laser down the fiber and watch reflections caused by imperfections. When vibrations hit the cable, it changes the defects, which show up in the return pattern. However, with the right techniques, those vibrations could just as easily be from people speaking near the cable.

If you are alarmed, there’s good news and bad news. The good news is that the technique seems to be limited to coils of fiber that are not buried, and you have to be within about 5 meters of the fiber. The bad news is that there is plenty of dark cable all over the place. Besides, if researchers can do this successfully, you would imagine three-letter agencies around the world could do it even better.

There have been several recent papers about the same topic. Of course, you can also read laser bounces from windows. Noisy keyboards can also give you away.

Title image from [Compare Fibre] via Unsplash.

If you ride a motorcycle, you know it is a bit of an art to manage the transmission on a typical bike. Electric motorcycles lose some of that. You usually just have a throttle and a brake. No transmission and, crucially, no clutch. Honda just patented a simulated clutch for those who want the old-school experience, according to [Ben Purvis], writing for Australian Motorcycle News.

This isn’t just a do-nothing lever on the handlebar. There’s haptic feedback to feel when the clutch engages. The motor responds to your actions on the lever. If you pull the clutch in part of the way, the motor loses power up to the point where there is no engine power with the clutch fully in.

Most interestingly, the software understands that when you raise the throttle with the clutch in and then release the clutch, you expect a sudden burst of torque, and it will accommodate the request.

If you are a casual driver, this may seem like a gimmick. However, according to the post, motocross racers rely on precise power control like this.

If you do your own conversion, you could probably do something similar. Or, we suppose, a new build, if you prefer.