Hardware Archive

I am a huge fan of my Rock 5 ITX+. It wraps an ATX power connector, a 4-pin Molex, PoE support, 32 GB of eMMC, front-panel USB 2.0, and two Gen 3×2 M.2 slots around a Rockchip 3588 SoC that can slot into any Mini-ITX case. Thing is, I never put it in a case because the microSD slot lives on the side of the board, and pulling the case out and removing the side panel to install a new OS got old with a quickness. I originally wanted to rackmount the critter, but adding a deracking difficulty multiplier to the microSD slot minigame seemed a bit souls-like for my taste. So what am I going to do? Grab a microSD extender and hang that out the back? Nay! I’m going to neuralyze the SPI flash and install some Kelvin Timeline firmware that will allow me to boot and install generic ARM Linux images from USB. ↫ Interfacing Linux Using EDK2 to add UEFI to an ARM board is awesome, as it solves some of the most annoying problems of these ARM boards: they require custom images specifically prepared for the board in question. After flashing EDK2 to this board, you can just boot any ARM Linux distribution – or Windows, NetBSD, and so on – from USB and install it from there. There’s still a ton of catches, but it’s a clear improvement. The funniest detail for sure, at least for this very specific board, is that the SPI flash is exposed as a block device, so you can just use, say the GNOME Disk Utility to flash any new firmware into it. The board in question is a Radxa ROCK 5 ITX+, and they’re not all that expensive, so I’m kind of tempted here. I’m not entirely sure what I’d need yet another computer for, honestly, but it’s not like that’s ever stopped any of us before.

You’ve seen them everywhere, especially on older computer equipment: the classic 9-pin serial connector. You probably know it as a DB9. It’s an iconic connector for makers, engineers, and anyone who’s ever used an RS232 serial device. Here’s a little secret, though: calling it a DB9 is technically wrong. The correct name is actually DE9. ↫ Christo-boots with the-pher at Sparkfun Electronics I honestly had no idea, and looking through the Wikipedia page, it seems this isn’t the only common misnomer when it comes to D-sub connectors.

GlobalFoundries today announced a definitive agreement to acquire MIPS, a leading supplier of AI and processor IP. This strategic acquisition will expand GF’s portfolio of customizable IP offerings, allowing it to further differentiate its process technologies with IP and software capabilities. ↫ Press release about the acquisition MIPS has a long and storied history, most recently as it abandoned its namesake instruction set architecture in favour of RISC-V. MIPS processors are still found in a ton of devices though, but usually not in high-profile devices like smartphones or whatever. Their new RISC-V cores haven’t yet seen a lot of uptake, but that’s a problem all across the RISC-V ecosystem.

The title is a lie. This isn’t brief at all. Picture the keypad of a telephone and calculator side by side. Can you see the subtle difference between the two without resorting to your smartphone? Don’t worry if you can’t recall the design. Most of us are so used to accepting the common interfaces that we tend to overlook the calculator’s inverted key sequence. A calculator has the 7–8–9 buttons at the top whereas a phone uses the 1–2–3 format. Subtle, but puzzling since they serve the same functional goal — input numbers. There’s no logical reason for the inversion if a user operates the interface in the same way. Common sense suggests the reason should be technological constraints. Maybe it’s due to a patent battle between the inventors. Some people may theorize it’s ergonomics. With no clear explanation, I knew history and the evolution of these devices would provide the answer. Which device was invented first? Which keypad influenced the other? Most importantly, who invented the keypad in the first place? ↫ Francesco Bertelli and Manoel do Amara Sometimes, you come across articles that are one-of-a-kind, and this is one of them. Very few people would go to this length to document such a particular thing most people find utterly insignificant, but luckily for us, Francesco Bertelli and Manoel do Amara went all the way with this one. If you want to know anything about the history of the numerical pad and its possibly layouts, this is the place to go. What I’ve always found fascinating about numerical pads is how effortless the brain can switch between the two most common layouts without really batting an eye. Both layouts seem so ingrained in my brain that it feels like there’s barely any context-switching involved, and my fingers just effortlessly flow to the correct numbers. Considering numbers tend to confuse me, I wouldn’t have been at all surprised to find myself having issues switching between the two layouts. What makes this even more interesting is when I consider the number row on the keyboard – you know, 1 through 0 – because there I do tend to have a lot of issues finding the right numbers. I don’t mean it takes seconds or anything like that, but I definitely experience more hiccups working with the number row than with a numerical keypad of either layout.

Late last year, I went on a long journey to rid myself of as much of my remaining ties to the big technology giants as I could. This journey is still ongoing, with only a few thin ties remaining, but there’s one big one I can scratch off the list: mobile in-store payments with NFC tap-to-pay. I used Google Pay and a WearOS smartwatch for this, but neither of those work on de-Googled Android – I opted for GrapheneOS – and it seemed like I was just going to have to accept the loss of this functionality. That is, until I stumbled upon a few forum posts here and there suggesting a solution: Garmin, maker of fitness trackers and smartwatches with a strong focus on sports, health, and the outdoor lifestyle, has its own mobile NFC tap-to-pay service that supposedly worked just fine on any Android device, de-Googled or not. In fact, people claimed you could even remove the companion Garmin application from your phone entirely after setting up the payment functionality, and it would still keep working. This seemed like something I should look into, because the lack of NFC tap-to-pay is a recurring concern for many people intending to switch to de-Googled Android. So, late last year, many of you chipped in, allowing me to buy a Garmin smartwatch to try this functionality out, for which I’m incredibly grateful, of course. Here’s how all of this works, and if it’s a good alternative for Google Pay. The Garmin Instinct 2S Solar First, let’s dive into which watch I chose to buy. Garmin has a wide variety of fitness trackers and smartwatches in its line-up, from basic trackers, to Apple Watch/WearOS-like devices, to outdoor-focused rugged devices. I opted for one of the outdoor-focused rugged devices, because not only would it give me the Garmin Pay functionality, but also a few other advantages and unique features I figured OSNews readers would be interested in: a simple black-and-white transflective memory-in-pixel display, a battery life measured in weeks (!), a solar panel built into the display glass, and a case constructed out of lightweight but durable plastics instead of heavy, scratch-prone metal. The specific model I opted for was the Instinct 2S Solar in Mist Grey. I wasn’t intending for this to become a review of the watch as a whole, but I figured I might as well share some notes about my experiences with this particular watch model. It’s important to note though that Garmin offers a wide variety of smartwatches, from models that look and feel mostly like an Apple Watch or wearOS device, to mechanical models with ‘invisible’ OLED displays on the dial, to ruggedised, button-only watches for hardcore outdoor people. If you’re interested in a Garmin device, there’s most likely a type that fits your wishes. The Instinct 2S is definitely not the most beautiful or attractive watch I’ve ever had on my wrist. It has that “rugged” look some people are really into, but for me, I definitely had to get used to it. I do really like the colour combination I opted for, though, as it complements the black/white transflective memory-in-pixel display really well. I’ve grown to… Appreciate the look over time. The case and bezel of the watch are made out of what Garmin calls “fiber-reinforced polymer”, which is probably just a form of fiber-reinforced plastic. Regardless of the buzzwords, it feels nice and sturdy, with a great texture, and not at all plasticy or cheap. Using a material like this over the metals the Apple Watch and most WearOS devices are made of has several advantages; first, it makes the device much lighter and thus more pleasant to wear, and it’s a lot sturdier and resilient than metals. I’ve banged this watch into door sills and countertops a few times now, and there’s not a scratch, dent, or discoloration on it – a far cry from the various metal Apple Watches and WearOS devices I own, which accumulated dings and scratches within weeks of buying them. The case material is one of the many ways in which this watch chooses function over form. Sure, metals might feel premium, but a high-quality plastic is cheaper to make, lasts longer, is more resilient, and also happens to be lighter – it’s simply the objectively better choice for something you wear on wrist every day, exposed to the elements. I understand why people want their smartwatch to be made out of metal, but much like how the orange-red plastic of the Nexus 5 is still the best smartphone material I’ve ever experienced (the white and black models uses inferior plastics), this Garmin tops all of the metal watches I own. The strap is made of silicone, and has an absurd amount of tightly-spaced adjustment holes, which makes it very easy to adjust to changing circumstances, like a bit of extra slack for when you’re working out. It also has a nice touch in that the second loop has a little peg that slots into an adjustment hole, keeping it in place. Ingenious. Other than that, it’s just a silicone band with the clasp made out of the same sturdy, pleasant “fiber-reinforced polymer” as the case. The lens over the display is made out of something Garmin calls “Power Glass™”, and I have no idea what that means. It just feels like a watch lens to me – solid, glassy, and… I don’t know, round? The unique aspect of the display glass is, of course, the built-in solar panel. It’s hard for me to tell what kind of impact – if any – the solar panel has on the battery life of the device. What quite obviously does not help is that I live in the Arctic where sun hours come at a bit of a premium, so it’s been impossible for me to stand outside and hold out my arm for a while to see if it had an effect on the charge level. There’s a software

The AlphaStation 500 is a workstation from Digital, circa 1996. Mine is a 500 MHz model and has an Alpha 21164A processor (aka EV56). And the way it boots is weird. On your common-or-garden PC, there has always been some kind of ROM chip. It holds a piece of firmware known as the BIOS. This ROM chip is available at a well-known location in the processor’s address space (remembering that any PC processor boots up in 16-bit, 8088 compatible mode, with a 1 MiB address space, just like an IBM PC 5150) and the processor just starts executing code in it after reset. The Alpha (or at least this AlphaStation 500 – although I think they mostly worked like this) is different. ↫ Jonathan ‘theJPster’ Pallant A great read, but a little bit over my head considering I’m anything but a programmer or developer. Still, even I managed to get the basic gist and learn quite a bit from this article, and especially the part about how the AlphaStation uses a little jumper to tell the SROM exactly which stream of boot code to send to the processor is fascinating. I’m not sure just how unusual the Alpha’s way of booting is, but I’d at least never heard of it.