Mysterious Files PH

Wednesday, July 15, 2026

FLOSS Weekly Episode 875: JavaScript as a Systems Language

July 15, 2026 0

This week Jonathan chats with Nariman Jelveh about Puter! It’s the project that takes the idea of the Browser-as-the-OS seriously. Why did a simulated desktop on the web take off, what the story of making it Open Source, and what’s coming next? Watch to find out!

Did you know you can watch the live recording of the show right on our YouTube Channel? Have someone you’d like us to interview? Let us know, or have the guest contact us! Take a look at the schedule here.

Direct Download in DRM-free MP3.

If you’d rather read along, here’s the transcript for this week’s episode.


Theme music: “Newer Wave” Kevin MacLeod (incompetech.com)

Licensed under Creative Commons: By Attribution 4.0 License


Hayabusa2’s Next Target is a Tiny 11 Meter Asteroid

July 15, 2026 0
Hayabusa2’s Next Target is a Tiny 11 Meter Asteroid

Launched in 2014, Japan’s Hayabusa2 spacecraft completed its primary asteroid sample return mission all the way back in 2020. But with the main spacecraft still healthy, the intrepid little probe was assigned new missions — such as its future investigation of asteroid 1998 KY26, a rather unassuming 11 meter diameter rock.

Artist impression of Hayabusa2 firing its ion thrusters. (Credit: DLR, Wikimedia)
Artist impression of Hayabusa2 firing its ion thrusters. (Credit: DLR, Wikimedia)

Earlier this month Hayabusa2 flew by the 450 meter 98943 Torifune at a distance of 800 meters, close enough to get an up-close look of its surface of mostly silicate minerals. With the spacecraft flying past at around 5 km/s, this posed some challenges with tracking, especially since its systems and instruments were not designed for high-speed tracking.

With that mission now complete, 1998 KY26 – first discovered in 1998 – is next on the menu, though this will have to wait a while. Currently it’s estimated that the two will not meet until July 2031.

Once they do meet up, after Hayabusa2 zips twice more past Earth, it’ll be another major challenge for the by now rather degraded spacecraft. Its sensors have suffer radiation and other types of damage, while its ion engines are quite depleted. The goal at this target asteroid is to enter orbit, deploy its last target marker and projectile, before attempting a landing, probably at one of its poles.

As likely the final mission for this spacecraft it’ll be very educational in many ways, not the least of which is that of planetary defense, but also that of deepening our understanding of these asteroids and the many varieties that we share space with.


Tuesday, July 14, 2026

Full Body VR Tracking Is Just Some Recycled Hardware Away

July 14, 2026 0
Full Body VR Tracking Is Just Some Recycled Hardware Away

Full body tracking in VR applications involves attaching sensors to one’s body, and [Jaki] has a DIY method to do it on the cheap: the Vive Tracker Lite project repurposes Vive controllers as lighthouse-based trackers, no hardware modifications required.

A common method of doing body tracking is to strap on some Vive trackers. Those are extremely hacker-friendly pieces of hardware, but [Jaki] observed that older Vive VR controllers can be had for cheap, and already contain everything a tracker needs. Some new firmware and a custom mount is all it takes to turn them into perfectly usable body trackers.

But what about a wireless receiver? [Jaki] has that covered as well with the $5 Viva Dongle, which uses a Pro Micro NRF52840 to act as a cheap DIY alternative to the official dongle hardware.

We appreciate the effort put into making this project accessible to everyone, even novices. [Jaki]’s put effort into a Python program with a full GUI to make the flashing of firmware as easy as possible for both projects. Experimenting with body tracking in VRChat or games with mods is just some recycled hardware away.

Granted, a Vive controller is not the slimmest piece of hardware, but all it takes is a firmware change and a 3D-printed fixture to make a perfectly serviceable tracker. That being said, we’re sure an enterprising hardware hacker may crack a controller open and embark on a serious rebuild, or even interface to some of the inputs in a clever way. If you’ve done that or know of someone who has, drop us a note on our tips line because we’d love to see it.


The Neo Geo Does Run DOOM After All

July 14, 2026 0
Demonstration of the DoomGeo port of Doom to the Neo Geo. (Credit: Sabino, GitHub)
Demonstration of the DoomGeo port of Doom to the Neo Geo. (Credit: Sabino, GitHub)

Perhaps the most ridiculous statement that anyone can make is that a computer system with clearly enough processing power ‘cannot run DOOM‘. This is why we accept the premise that a PDP-11 cannot run this game, but something on the order of a Neo Geo gaming console with its 68000 processor and for the time impressive GPU definitely ought to be able to.

The stated problem here is a lack of RAM for a framebuffer, with the CPU only having 64 kB to play with. This limitation now has seen two different approaches to try and circumvent it, as covered by [Modern Vintage Gamer].

The first project here is Doom64kB, which as the name suggests tries to somehow work with this system RAM limitation. It uses the Doom8088 port for the original IBM PC and similar Intel 8088-based systems. This had to massively reduce the feature list, including the lack of texture mapping for floors and ceiling, no saving or loading, and no music.

The other project is DoomGeo, which doesn’t try to bend the Neo Geo hardware to its will, but accepts the Neo Geo way of doing things: involving sprite strips, pre-baked graphics, fix-layer UI, and a minimum of runtime data. This of course drastically changes how the Doom game engine normally works, with its framebuffer-based rendering.

From this we can thus conclude that it’s not so much the processing power that limits where DOOM can run, but more of how framebuffer-friendly the system architecture is, yet with some ingenuity and a complete rewrite of the game engine even that is no major obstacle.

(Top image: Neo Geo AES console. Credit: Evan-Amos, Wikimedia)


2026 Frikkin Lasers Challenge: Laser Bandsaw

July 14, 2026 0
2026 Frikkin Lasers Challenge: Laser Bandsaw

Can you call it a bandsaw if it has neither band nor saw? [WeldingRod1] does, with his entry in the laser contest — a manually-controlled laser cutter that he’s dubbed a Laser Bandsaw. Some might quibble that it’s not actually sawing with the beam, and others will inevitably find the safety implications rather frightening. We think it’s a fun project and that [WeldingRod1] can call it what he wants, as long as he follows his own advice and keeps his laser goggles firmly on his precious vision orbs.

He has actually put some thought into what started as the physical manifestation of a joke in a podcast. The blue diode laser — a NUBM44 diode rated at 7 W — got a custom-made copper heatsink. It’s also got a hefty beam dump in the form of a stack of box knife blades. That’s very necessary to keep the beam from reflecting where it shouldn’t, especially when you consider this operates like a regular band saw: you turn it on, and it’s ready to cut. With only 7 W of laser power it can’t cut that much, mind you, but apparently it’s great on balsa wood and blasts black paint off like nobody’s business.

Now if this was our shop we’d probably want to put the laser diode onto some kind of CNC platform, be it Cartesian or SCARA. But we’ve seen that done many, many times and if you’ve got the motor skills this might be just the tool for you. There’s a pinout and STLs for the 3D printed frame on the project page if you’re interested. If not, why are you still here? The article is finished. Go make something lase and send it in. The deadline for the 2026 Frikkin Laser Contest is fast approaching!


Fibrous Muscles for Humanoid Robotics

July 14, 2026 0

At the current rate of robotics development, you might assume that we’re close to Skynet taking over. However, while we  likely wouldn’t do well in a physical fight against a robot, we can at least keep the bragging rights of having the cooler actuators. Or at least, that was the case before a new actuator came into town — introducing “Electrofluidic Fiber Muscles”.

Traditional robotic actuators use motors of some kind with a variety of gearboxes or linkages to turn rotational movement into usable movement. This isn’t always the most effective way to run some robotics movements, especially when modeling humans. This is why many have turned to pressurized modes of actuation. Though most don’t show quite the promise of the new player.

Electrofluidic Fiber Muscles use pressure to shorten muscle strands, similar to past actuators. However, these are a tad different, taking advantage of electrofluidic pressure. A small current under high voltage is able to drive a pressure gradient in a long tube. This tube can then be connected to both an extensor and flexor portion of an actuating circuit, similar to a biological mechanical system. Better yet, this driving pressure pump can be spun around the fibers themselves, making a tight package.

Unfortunately, it will probably be a bit till we see this inside a hobbyist robot. Until then, make sure to check out some other actuator feats!


Monday, July 13, 2026

Using Your Own RBMK Reactor Control Center At Home

July 13, 2026 0

To give people the most intimate RBMK experience, the [Chornobyl Family] has been working tirelessly at not only replicating the original RBMK reactor control room and its SKALA industrial control system’s controls, but also to create a version that you could tinker with at home if you ever fancied getting your own RBMK operator license. This starts with the operator console, with its use demonstrated in a recent video including a range of common commands.

In this video the entering of codes on the console to interact with the system is detailed, including the logic behind it. In the absence of large displays to display many parameters and such, this way the operator could ‘talk’ with the control system, including obtaining current sensors readings and the setting and changing of setpoints. From the same console you can also select and run programs, which is useful for automating tasks, like monitoring coolant flows.

In the second video not only the construction of the control panel is covered, but also a visual representation of the simulated reactor core which is displayed on a connected monitor. Although not a part of the original SKALA system as such, a much larger version existed as a wall-sized physical version inside the control room, so it’s definitely more home-simulator friendly.

We previously covered this SKALA system that controls RBMK reactors, as well as the 1990s modernization of the Chornobyl Nuclear Power Plant.