Designing A Portable Mac Mini

When Apple first launched the Macintosh, it created a new sort of “Lunchbox” form factor that was relatively portable and very, very cool. Reminiscent of that is this neat portable Macintosh Mini, created by [Scott Yu-Jan].

[Scott] has created something along these lines before—putting an iPad dock on top of a Macintosh Studio to create a look vaguely reminiscent of the very first Macintosh computers. However, that build wasn’t portable—it wasn’t practical to build such a thing around the Macintosh Studio. In contrast, the Mac Mini is a lithe, lightweight thing that barely sups power—it’s much more suitable for a “luggable” computer.

The build relies on a 3D printed enclosure that wraps around the Mac Mini like a glove. Inside, there’s a chunky 20,800 mAh power bank with enough juice to run the computer for over three hours. Just like the original Mac, there’s a handle on top, too. The build’s main screen is actually an iPad Mini, hooked up to the Mac Mini. If you want to use it separately, it can be popped out just by pushing it via a cutout in the bottom of the enclosure.

[Scott] notes that it’s cool, but not exactly practical—it weighs seven pounds, mostly due to the weight of the heavy power bank. We’ve featured [Scott’s] stylish builds before, too, like this nice iPhone dock.

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Physical Key Copying Starts With A Flipper Zero

A moment’s inattention is all it takes to gather the information needed to make a physical copy of a key. It’s not necessarily an easy process, though, so if pen testing is your game, something like this Flipper Zero key copying toolchain can make the process quicker and easier when the opportunity presents itself.

Of course, we’re not advocating for any illegal here; this is just another tool for your lock-sports bag of tricks. And yes, there are plenty of other ways to accomplish this, but using a Flipper Zero to attack a strictly mechanical lock is kind of neat. The toolchain posted by [No-Lock216] starts with an app called KeyCopier, which draws a virtual key blank on the Flipper Zero screen.

The app allows you to move the baseline for each pin to the proper depth, quickly recording the bitting for the key. Later, the bitting can be entered into an online app called keygen which, along with information on the brand of lock and its warding, can produce an STL file suitable for downloading and printing.

Again, there are a ton of ways to make a copy of a key if you have physical access to it, and the comments of the original Reddit post were filled with suggestions amusingly missing the entire point of this. Yes, you can get a key cut at any hardware store for a buck or two that will obviously last a lot longer than a 3D printed copy. But if you only have a few seconds to gather the data from the key, an app like KeyCopier could be really convenient. Personally, we’d find a smartphone app handier, but if you’ve got a Flipper, why not leverage it?

Thanks to [JohnU] for the tip.

Brazilian Modders Upgrade NVidia Geforce GTX 970 To 8 GB Of VRAM

Although NVidia’s current disastrous RTX 50-series is getting all the attention right now, this wasn’t the first misstep by NVidia. Back in 2014 when NVidia released the GTX 970 users were quickly dismayed to find that their ‘4 GB VRAM’ GPU had actually just 3.5 GB, with the remaining 512 MB being used in a much slower way at just 1/7th of the normal speed. Back then NVidia was subject to a $30/card settlement with disgruntled customers, but there’s a way to at least partially fix these GPUs, as demonstrated by a group of Brazilian modders (original video with horrid English auto-dub).

The mod itself is quite straightforward, with the original 512 MB, 7 Gbps GDDR5 memory modules replaced with 1 GB, 8 Gbps chips and adding a resistor on the PCB to make the GPU recognize the higher density VRAM ICs. Although this doesn’t fix the fundamental split VRAM issue of the ASIC, it does give it access to 7 GB of faster, higher-density VRAM. In benchmarks performance was massively increased, with Unigine Superposition showing nearly a doubling in the score.

In addition to giving this GTX 970 a new lease on life, it also shows just how important having more VRAM on a GPU is, which is ironic in this era where somehow GPU manufacturers deem 8 GB of VRAM to be acceptable in 2025.

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LED Filaments Become Attractive Time Piece

There are a million ways to use LEDs to make a clock. [sjm4306] chose to go a relatively conventional route, making something that approximates a traditional analog timepiece. However, he did it using LED filaments to create a striking and unique design. Thus the name—FilamenTIME!

LED filaments are still relatively new on the scene. They’re basically a bunch of tiny LEDs mounted in a single package to create a single “filament” of light that appears continuous. It’s great if you want to create a bar of light without messing around with populating tons of parts and having to figure out diffusion on your own.

[sjm4306] used them to create glowing bar elements in a clock for telling the time. The outer ring contains 60 filaments for the 60 minutes in an hour, while the inner ring contains 12 filaments to denote the hours themselves. To handle so many LEDs, there are 9 shift registers on board. They’re driven by an ATmega328P which runs the show, with a DS3232MZ real-time clock onboard for keeping time.  As you might imagine, creating such a large circular clock required a large PCB—roughly a square foot in size. It doesn’t come cheap, though [sjm4306] was lucky enough to have sponsorship to cover the build. [sjm4306] is still working on the firmware, and hopes to build a smaller, more compact version, which should cut costs compared to the large single board.

It’s a neat clock, and we’d know, having seen many a timepiece around these parts. Video after the break.

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The Vectrex Home Computer You Never Had

The Vectrex console from the early 1980s holds a special place in retrocomputing lore thanks to its vector display — uniquely for a home system, it painted its graphics to the screen by drawing them with an electron beam, instead of scanning across a raster as a TV screen would. It thus came with its own CRT, and a distinctive vertical screen form factor.

For all that though, it was just a games console, but there were rumors that it might have become more. [Intric8] embarked on a quest to find some evidence, and eventually turned up what little remains in a copy of Electronic Games magazine. A keyboard, RAM and ROM expansion, and a wafer drive were in the works, which would have made the Vectrex a quirky equal of most of what the likes of Commodore and Sinclair had to offer.

It’s annoying that it doesn’t specify which issue of the magazine has the piece, and after a bit or browsing archive.org we’re sorry to say we can’t find it ourselves. But the piece itself bears a second look, for what it tells us about the febrile world of the 8-bit games industry. This was a time of intense competition in the period around the great console crash, and developers would claim anything to secure a few column inches in a magazine. It’s not to say that the people behind the Vectrex wouldn’t have produced a home computer add-on for it if they could have done, but we remember as teenagers being suckered in by too many of these stories. We still kinda want one, but we’d be surprised if any ever existed.

If you have a Vectrex, it’s possible to give it a light pen.

Ancient Pocket Computer Gets A Serious Serial Upgrade

[Robert’s Retro] is one of those great YouTube channels that shows us the ins and outs of old and obscure computers. [Robert] likes going a step beyond the traditional teardown though, repairing and upgrading these old machines. His latest project involves giving the ZEOS Pocket PC a fully-functional serial port. 

If you’re unfamiliar with the ZEOS Pocket PC, you might know it as the Tidalwave PS-1000—it’s a pretty straightforward clone. Originally, these machines could be had with a proprietary serial adapter to enable them to interface with external peripherals. However, like most obscure cables and connectors from three decades ago, they’re virtually unobtainable today.

To solve this problem, [Robert] decided to hack in a traditional DE-9 connector instead. Commonly referred to as the DB-9, this is the most common serial port design used on IBM PCs and compatibles. Getting the larger port into the compact PC required some careful hacking of the case, as well as delicate soldering to hook up the pins to the right signals on the tightly-packed motherboard. This video does involve cutting some vintage plastic, but overall it’s a very neat mod that is handled with due respect and care.

This isn’t the first time we’ve seen him upgrade a classic portable computer, either.

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Supercon 2024: Killing Mosquitoes With Freaking Drones, And Sonar

Suppose that you want to get rid of a whole lot of mosquitoes with a quadcopter drone by chopping them up in the rotor blades. If you had really good eyesight and pretty amazing piloting skills, you could maybe fly the drone yourself, but honestly this looks like it should be automated. [Alex Toussaint] took us on a tour of how far he has gotten toward that goal in his amazingly broad-ranging 2024 Superconference talk. (Embedded below.)

The end result is an amazing 380-element phased sonar array that allows him to detect the location of mosquitoes in mid-air, identifying them by their particular micro-doppler return signature. It’s an amazing gadget called LeSonar2, that he has open-sourced, and that doubtless has many other applications at the tweak of an algorithm.

Rolling back in time a little bit, the talk starts off with [Alex]’s thoughts about self-guiding drones in general. For obstacle avoidance, you might think of using a camera, but they can be heavy and require a lot of expensive computation. [Alex] favored ultrasonic range finding. But then an array of ultrasonic range finders could locate smaller objects and more precisely than the single ranger that you probably have in mind. This got [Alex] into beamforming and he built an early prototype, which we’ve actually covered in the past. If you’re into this sort of thing, the talk contains a very nice description of the necessary DSP.

[Alex]’s big breakthrough, though, came with shrinking down the ultrasonic receivers. The angular resolution that you can resolve with a beam-forming array is limited by the distance between the microphone elements, and traditional ultrasonic devices like we use in cars are kinda bulky. So here comes a hack: the TDK T3902 MEMS microphones work just fine up into the ultrasound range, even though they’re designed for human hearing. Combining 380 of these in a very tightly packed array, and pushing all of their parallel data into an FPGA for computation, lead to the LeSonar2. Bigger transducers put out ultrasound pulses, the FPGA does some very intense filtering and combining of the output of each microphone, and the resulting 3D range data is sent out over USB.

After a marvelous demo of the device, we get to the end-game application: finding and identifying mosquitoes in mid-air. If you don’t want to kill flies, wasps, bees, or other useful pollinators while eradicating the tiny little bloodsuckers that are the drone’s target, you need to be able to not only locate bugs, but discriminate mosquitoes from the others.

For this, he uses the micro-doppler signatures that the different wing beats of the various insects put out. Wasps have a very wide-band doppler echo – their relatively long and thin wings are moving slower at the roots than at the tips. Flies, on the other hand, have stubbier wings, and emit a tighter echo signal. The mosquito signal is even tighter.

If you told us that you could use sonar to detect mosquitoes at a distance of a few meters, much less locate them and differentiate them from their other insect brethren, we would have thought that it was impossible. But [Alex] and his team are building these devices, and you can even build one yourself if you want. So watch the talk, learn about phased arrays, and start daydreaming about what you would use something like this for.

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