You Know This Font, But You Don’t Really Know It

February 15, 2025 by 18 Comments

Typography enthusiasts reach a point at which they can recognise a font after seeing only a few letters in the wild, and usually identify its close family if not the font itself. It’s unusual then for a font to leave them completely stumped, but that’s where [Marcin Wichary] found himself. He noticed a font which many of you will also have seen, on typewriter and older terminal keys. It has a few unusual features that run contrary to normal font design such as slightly odd-shaped letters and a constant width line, and once he started looking, it appeared everywhere. Finding its origin led back well over a century, and led him to places as diverse as New York street furniture and NASA elevators.

The font in question is called Gorton, and it came from the Gorton Machine Co, a Wisconsin manufacturer. It’s a font designed for a mechanical router, which is why it appears on so much custom signage and utilitarian components such as keyboard keys. Surprisingly its history leads back into the 19th century, predating many of the much more well-know sans serif fonts. So keep an eye out for it on your retro tech, and you’ll find that you’ve seen a lot more of it than you ever knew. If you are a fellow font-head, you might also know the Hershey Font, and we just ran a piece on the magnetic check fonts last week.

Thanks [Martina] for the tip!

Octet Of ESP32s Lets You See WiFi Like Never Before

February 15, 2025 by 14 Comments

Most of us see the world in a very narrow band of the EM spectrum. Sure, there are people with a genetic quirk that extends the range a bit into the UV, but it’s a ROYGBIV world for most of us. Unless, of course, you have something like this ESP32 antenna array, which gives you an augmented reality view of the WiFi world.

According to [Jeija], “ESPARGOS” consists of an antenna array board and a controller board. The antenna array has eight ESP32-S2FH4 microcontrollers and eight 2.4 GHz WiFi patch antennas spaced a half-wavelength apart in two dimensions. The ESP32s extract channel state information (CSI) from each packet they receive, sending it on to the controller board where another ESP32 streams them over Ethernet while providing the clock and phase reference signals needed to make the phased array work. This gives you all the information you need to calculate where a signal is coming from and how strong it is, which is used to plot a sort of heat map to overlay on a webcam image of the same scene.

The results are pretty cool. Walking through the field of view of the array, [Jeija]’s smartphone shines like a lantern, with very little perceptible lag between the WiFi and the visible light images. He’s also able to demonstrate reflection off metallic surfaces, penetration through the wall from the next room, and even outdoor scenes where the array shows how different surfaces reflect the signal. There’s also a demonstration of using multiple arrays to determine angle and time delay of arrival of a signal to precisely locate a moving WiFi source. It’s a little like a reverse LORAN system, albeit indoors and at a much shorter wavelength.

There’s a lot in this video and the accompanying documentation to unpack. We haven’t even gotten to the really cool stuff like using machine learning to see around corners by measuring reflected WiFi signals. ESPARGOS looks like it could be a really valuable tool across a lot of domains, and a heck of a lot of fun to play with too.

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How To Find Where A Wire In A Cable Is Broken

February 15, 2025 by 43 Comments

Determining that a cable has a broken conductor is the easy part, but where exactly is the break? In a recent video, [Richard] over at the Learn Electronics Repair channel on YouTube gave two community-suggested methods a shake to track down a break in a proprietary charging cable. The first attempt was to run a mains power detector along the cable to find the spot, but he didn’t have much luck with that.

The second method involved using the capacitance of the wires, or specifically treating two wires in the cable as the electrodes of a capacitor. Since the broken conductor will be shorter, it will have less capacitance, with the ratio theoretically allowing for the location of the break in the wire to be determined.

In the charging cable a single conductor was busted, so its capacitance was compared from both sides of the break and compared to the capacitance of two intact conductors. The capacitance isn’t much, on the order of dozens to hundreds of picofarads, but it’s enough to make an educated guess of where the rough location is. In this particular case the break was determined to be near the proprietary plug, which ruled out a repair as the owner is a commercial rental shop of e-bikes.

To verify this capacitor method, [Richard] then did it again on a piece of mains wire with a deliberate cut to a conductor. This suggested that it’s not a super accurate technique as applied, but ‘good enough’. With a deeper understanding of the underlying physics it likely can be significantly more accurate, and it’s hardly the only way to find broken conductors, as commentators to the video rightly added.

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Valentine Heart

Valentine’s Day…Hacks?

February 15, 2025 by 7 Comments

How do you reconcile your love for hacking projects together with your love for that someone special? By making him or her a DIY masterpiece of blinking red LEDs, but in heart shape. Maybe with some custom animations, and in a nice frame with a capacitive touch sensor to turn it on or off.

Or at least, that’s what I did. The good news is that my girlfriend, now wife, understands that this sort of present comes from a place of love. And it probably didn’t hurt that I also picked up some flowers to frame it with, and cooked her favorite lunch later that afternoon.

But if I’m 100% frank with myself, I’d have to admit that this was about 50% “present” and 50% “project”. Of course it also helps that she gets me, and that she knows that I put a bunch of effort into making it look as good as it did, and maybe because of that she forgives the 50% project.

Valentine’s day projects are a high-wire balancing act. If any other project fails, you can just try again. But here, the deadline is firm. Cosmetics matter a lot more on Valentine’s day than the other 364 days of the year, too. And finally, you really have to know the gift-receiver, and be sure that you’re not falling deeper into the excuse-for-a-cool-project trap than I did. And don’t forget the flowers.

I pulled it off with this one, at least, but I do feel like it was close, even today. Have you ever made a Valentine’s hacking project? How’d it go?

(Note: Featured image isn’t my project: It’s a lot more colorful!)

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Adding USB-C (Kinda) To A PowerMac G4

February 15, 2025 by 10 Comments

For those who’ve never bitten the Apple, the PowerMac G4 was a blue-tinted desktop Macintosh offered from 1999 to 2004. At the time, the machines were plenty fast — being advertised as the first “personal supercomputer” when they hit the market. But Father Time is particularly harsh on silicon, so they’re properly archaic by modern standards.

As such, the rear panel of one of these machines is hardly where you’d expect to run into a functional USB-C port. But thanks to the efforts of [Dandu], old has officially met new. Critics will note that it’s not real USB-C, and instead uses USB 2.0 with the more modern connector. That’s true, but considering how many commercial devices we run into that are still using the same trick, we’ll give it a pass.

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Game Bub Plays ROMs And Cartridges

February 15, 2025 by 10 Comments

With today’s technology, emulating video game consoles from the 90s or before is trivial. A Raspberry Pi and a controller of some sort is perhaps the easiest and simplest way to go to get this job done, but to really impress the masses some extra effort is required. This handheld from [Eli] called the Game Bub not only nails the appearance and feel of the first three generations of Nintendo handhelds but, thanks to its FPGA, can play not only ROMs but the original game cartridges as well.

As [Eli] notes, the FPGA is not strictly necessary for emulation, but does seem to be better at interfacing with physical hardware like controllers and game cartridges. For this task an Xilinx XC7A100T with integrated memory was chosen, with a custom PCB supporting the built-in controller, speaker, a rechargeable lithium battery, and a 480×320 display (that had to be rotated out of portrait mode). An SD Card reader is included for any ROM files, and there’s also a ESP32-S3 included to give the handheld WiFi and Bluetooth capabilities, with future plans to support the communications protocol used by the Game Boy Advance Wireless Adapter.

There are a few other features with the Game Bub as well, including the ability to use an authentic link cable to communicate with the original Game Boy and Game Boy Color, and a Switch-like dock that allows the Game Bub to be connected to an external monitor. It’s also open source, which makes it an even more impressive build. Presumably it doesn’t include the native ability to dump cartridges to ROM files but you don’t need much more than a link cable to do that if you need to build your ROM library.

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A Guide To Making The Right Microcontroller Choice

February 14, 2025 by 50 Comments

Starting a new microcontroller project can be pretty daunting. While you have at least a rough idea of where you want to end up, there are so many ways to get there that you can get locked into “analysis paralysis” and never get the project off the ground. Or arguably worse, you just throw whatever dev board you have in the junk bin and deal with the consequences.

While it’s hard to go wrong with relying on a familiar MCU and toolchain, [lcamtuf] argues in this recent guide to choosing microcontrollers that it’s actually not too much of a chore to make the right choice. Breaking the microcontroller universe down into three broad categories makes the job a little easier: simple process control, computationally intensive tasks, and IoT products. Figuring out where your project falls on that spectrum narrows your choices considerably.

For example, if you just need to read some sensors and run a few servos or solenoids, using something like a Raspberry Pi is probably overkill. On the other hand, a Pi or other SBC might be fine for something that you need wireless connectivity. We also appreciate that [lcamtuf] acknowledges that intangible considerations sometimes factor in, such as favoring a new-to-you MCU because you’ll get experience with technology you haven’t used before. It might not override technical considerations by itself, but you can’t ignore the need to stretch your wings once in a while.

There’s nothing earth-shattering here, but we enjoy think pieces like this. It’s a bit like [lcamtuf]’s recent piece on rethinking your jellybean op-amps.