Along with Velcro, zippers have become an integral part of every day life, being a quick and easy way to usually temporarily join fabric together. Which isn’t to say that you cannot do more with the basic zipper concept, including using them to turn floppy 2D shapes into rigid 3D ones, such as with the Y-zipper concept proposed and demonstrated by [Jiaji Li] et al.

Although not a fully new idea, the Y-zipper is compared with a range of similar mechanisms that do not feature the same abilities, including the standard zipper ease of zipping up, the possibility of having curved geometry and automatic actuation.

Plus there is that the Y-zipper is designed from the start to be 3Dprinted, while still following the same basic pattern of interlocking teeth that the slider mechanism alternately pushes together or pulls apart.

By modifying the basic straight design of the flat strips, the resulting zipped-up form can take on a distinct bend, as well as turn into a coil or a screw. With a demonstrated joint design it is then possible to join multiple Y-zipper rods together, which could make for an interesting alternative to traditional pop-up tent supports, for example.

Also demonstrated is the use of TPU to create compliant bridges, as well as the direct integration of fabric, to show the versatility of the technology. With the used materials (PLA, TPU) the researchers estimate a maximum viable length of about 3 meters before the printed structures begin to disintegrate.

hackaday.com/2026/05/13/y-zipp…

You’ve probably seen a Foucault pendulum in a museum. This Victorian-era science demonstration is named after physicist Léon Foucault and shows how the Earth rotates compared to a pendulum moving in a fixed plane. [RyanCreates] shows you how you can make your own, and it is surprisingly simple.

All you need is a heavy weight like a small mushroom anchor, fishing line, and a swivel — all things you can pick up at any sporting goods store. You’ll need a way to suspend it all, such as an eye hook in the ceiling.

In addition to the mechanical parts, the build calls for a camera to record the results and a lighter or other source of flame. The reason? To release the pendulum, you burn a thread that prevents it from swinging. This allows for a clean release with no sideways force.

The amount of your rotation depends on your latitude. At 33 degrees north, for example, you can expect 360*sin(33)/24 or 8.17 degrees per hour of rotation. [Ryan] measured a somewhat larger number, which was probably due to an error source, especially since he is measuring the angle using captured camera frames in Photoshop. That has to introduce some error, and small pendulums like this are incredibly sensitive to errors.

If you try it and find the source of the error, we’re sure [Ryan] would love to hear from you. Museum pieces are typically much larger, have ultra-low-friction pivots, and use electromagnets to keep the pendulum moving since, after all, even a Foucault pendulum can’t run forever.

hackaday.com/2026/05/13/measur…

Originally envisioned as a simple DIY laptop project, [kati]’s PinkPad V1 ended up being considerably more involved than expected. But the end result is a perfectly usable, stunningly pink, and remarkably sturdy portable laptop that looks nothing like a hack job.
Originally a VTech toy, the PinkPad is a perfectly functional DIY laptop.
The PinkPad V1 started as a toy laptop for toddlers, repurposed into a DIY laptop running Linux while keeping the original clamshell design and cute aesthetic. As [kati] herself points out, while it may not seem particularly difficult to yank out a toy’s insides and stuff it with a Raspberry Pi, most of the real challenges were related to actually getting all the necessary parts and connectors and wiring to actually fit in a useful way. As anyone with experience in building something knows, working around existing enclosures or hardware almost always brings unexpected challenges.

The original toy laptop? Produced by none other than VTech, whose products have been hacked to create things like a punch card-reading cyberdeck and Z80 hacking station. Our own [Tom Nardi] has also shared his fondness for these devices in several teardowns over the years.

In the end, [kati]’s PinkPad ended up sporting a mini keyboard (whose black keys were turned pink with a little nail polish) and a 5 inch touchscreen LCD. Combined with a rechargeable power supply, it provides all the comforts of an Arch Linux ARM mini laptop.

Thanks [alex] for the tip!

hackaday.com/2026/05/13/vtech-…

It’s possible that among Hackaday readers are the largest community of people who have designed their own CPU in the world. We have featured many here, but it’s possible that not so many of them have gone on to power an everyday project. Step forward [Baltazar Studios] then, with a scientific calculator sporting a self-designed CPU on an FPGA.

The calculator itself is nice enough, with a smart 3D printed case, an OLED display which almost evokes a VFD, and very well made buttons. But it’s the CPU which is of most interest, because while it follows a conventional Harvard architecture with a 12-bit instruction set, it works with 4-bit nibbles. This choice follows one used by HP in their calculator designs, seemingly because it can be optimised for the binary coded decimal which the calculator uses.

With calculators being yet another app on our spartphones or comnputers, there seems to be less use of calculators outside of education in 2026. But if you are a calculator user there’s nothing like a calculator you made yourself, and with a CPU of your own design it has few equals. We like this project almost as much as we like the Flapulator!

hackaday.com/2026/05/13/build-…

The Hindenburg disaster recently marked its 89th anniversary, and [The History Guy] marked the event with a video that dispels many of the myths surrounding the airship. Example: the disaster did not actually occur on the airship’s maiden voyage. That isn’t true. The ship was on its 63rd voyage. However, it was the first flight of the 1937 season.

The giant ship burned because of the hydrogen gas inside, but the cause of the fire remains debatable and was likely not solely due to hydrogen. In fact, from a technical standpoint, the ship didn’t explode. It only burned.

Some of the myths are just from sloppy reporting or the tendency of people to misunderstand things. Others are a blurring in the common consciousness of the Hindenburg and the Titanic.

It is easy to think of the necessity for safe engineering when you are building, say, a bomb or a spacecraft. But anything capable of wreaking havoc requires careful design and testing. However, ships like the Hindenburg had made many trips without incident. Sure, the Hindenburg was a spectacle, but even the fatality rate was fairly low. Many of those who died jumped to the ground — they might have survived if they had waited a minute.

There are many myths around [Herb Morrison]’s famous “Oh the humanity!” report. We’ve noted before that it was played back at the wrong speed for decades. Airships have a stranger history than you might imagine.

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hackaday.com/2026/05/12/the-tr…

Arbitrary command execution with the Wi-Fi password. (Credit: Benn Jordan)
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.

youtube.com/embed/lA8WuXDXfcI?…

hackaday.com/2026/05/12/the-da…

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.

youtube.com/embed/R1fHld9Nwww?…

hackaday.com/2026/05/12/trying…

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.

youtube.com/embed/9-0OKkkqMc0?…

hackaday.com/2026/05/12/crts-a…

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.

youtube.com/embed/j262kCYZxZI?…

hackaday.com/2026/05/12/a-cybe…

With Hackaday Europe no more than two days away, we want to help you wrap up all of the last loose ends. And that means last-minute changes in the workshop schedule, details on the Thursday night pre-party, and more! Some tickets for the event itself, the workshops, and the pre-party (reservations required) are still available right here.

Pre-Party, Thurs May 15th

Kick off the weekend with us at the official Hackaday Europe pre-party at Soqquadro Restaurant, Piazza Era 7, 23900 Lecco, Italy. Enjoy the Italian aperitivi on the gorgeous Lago di Lecco waterfront. Your ticket includes two drinks and an array of delicious snacks. It’s the Italian way to pregame the weekend ahead. Bring a hack, or just relax and hang out. Your choice. Either way, make sure you pre-register. (On the preregistration page, scroll all the way down past the workshops.)

Workshops

Unfortunately, the Let’s Mesh workshop has been canceled, but the good news, thanks to our incredible sponsors, we’ve added two great new workshops to the lineup. On Saturday, May 16th, we’ll have Tiny Tapeout, When Code Needs a Body, and Fault Injection 101. Sunday features EchoGlow: Arduino UNO Q Workshop with the brand-new Arduino Q devices, from 11:00 AM – 2:00 PM.

Tickets and full descriptions are available at registration.

Lightning Talks

On Sunday afternoon, we’ll dedicate some time to Lightning Talks. These are short, seven-minute talks, with or without slides, on whatever interests you at the moment. If you’ve got hacks or deep thoughts to share with us, you’ll never find a more receptive audience. Register now! Talk slots are FIFO.

Thanks, and See You Soon!

If you’ve never attended a Hackaday event before, we’re excited to see you. Half the fun is the crowd that convenes. If you want to bring along a hack to informally show-and-tell, it’s a great icebreaker. You won’t have to bring food or drinks – we’ve got that covered all weekend.

If you’re an old Hackaday hand, we’re stoked to see you again! A first at Hackaday Europe is going to be whatever large fraction of our SAO collection fits into carry-on luggage, and a sweet-looking SAO wall made by Hackaday Superfriend [Thomas Flummer]. If you have an SAO that you’d like to add to our pile, bring it along! It’s about time for us to do a photo gallery and write-up of everything we’ve got.

And we can’t leave without thanking our broad array of sponsors who make Hackaday Europe possible:

• element14
• Makera
• Espressif
• Arduino
• iFixit
• Edge Impulse
• FibreSeek
• Tiny Tapeout
• And as always, Supplyframe!

hackaday.com/2026/05/12/2026-h…

If you bought computer audio hardware a few decades ago, you may remember coming across products from Altec Lansing. That you probably haven’t thought of that name in some time doesn’t surprise us, the company has not fared well in recent years and has changed hands multiple times. [The Last Shift] tells the company’s history in a video you can watch below.

James Lansing started Lansing Manufacturing, offering high-end speakers for the fledgling “talkie” movie industry. It had some success, but the depression put them on shaky footing. Meanwhile, a company named All Technical Service Company, or Altec, was a large organization that serviced Western Electric movie theater equipment. Flush with cash, they merged with Lansing Manufacturing to form Altec Lansing. With a large infrastructure and Lansing’s engineering, they became a significant supplier to the military during World War II.

After the war, the company produced a landmark theater speaker system that became the gold standard in theater audio. However, Lansing didn’t like the big company environment and left to found a company that bore his full name, James B. Lansing, which you may know as JBL.

Altec Lansing continued to grow. However, a series of mergers and sales starting in 1969 caused the Altec Lansing company to decline. By the 1990s, Altec Lansing was making cheap PC speakers. A far cry from the gold-standard massive speakers made by the company during its heyday.

We love the history of technology and the people that drove them. Bing Crosby, for example. Or the lesser-known heroes like Edwin Armstrong.

youtube.com/embed/l1URAymcu6Y?…

hackaday.com/2026/05/12/the-hi…

The quest for true randomness has roots in cryptography and is a rabbit hole that gets surprisingly deep with alarmingly rapidity. Still, the generation of random-enough numbers is a popular hacker project. Part of the appeal is the way these devices strive to incorporate physical phenomena, and in [Joshua Coleman]’s case, his Neon Entropy (Pseudo) Random Number Generator uses a trio of vintage neon lamps.
Neon lamps discharge at rates that vary unpredictably. They’re also pretty to look at.
[Joshua] chose neon lamps in part because the discharge rate of an energized lamp is a variable, physical process that makes a good source of entropy. They also have an attractive visual appeal that fits the concept [Joshua] had in mind. Unlike random number generators that kick off by measuring radiation or some other imperceptible thing, it’s possible — at least in a sense — to see this one working.

The small variations in the three neon lamps are measured optically by three TEPT4400 ambient light sensors (isolated from the neon lamps themselves) and turned into analog signals. A Raspberry Pi Pico W reads these signals, then uses them in a process that culminates in SHA-256 64-bit values that can be used as random seeds.

There’s also a web dashboard that shows everything live, furthering the “watch it work” concept [Joshua] is aiming for. The video below shows the project in action if you want to see how the sausage gets made.

Earlier we mentioned how random number generators are popular projects among hackers, and here are a few selected ones. Don’t miss the stylish glow and slick enclosure of this Nixie tube RNG, or the lava lamp RNG which is in fact not a gimmick. And while it is commonly understood that meaningful randomness must come from outside a digital chip, uninitialized internal volatile RAM — if accessed correctly — can be a remarkably good source of entropy.

youtube.com/embed/FoSpGV7inyA?…

hackaday.com/2026/05/12/this-p…

As the foremost boffins of Europe toil deep underneath the border between Switzerland and France in their never-ending quest to truly understand the fabric of the Universe, they rely on a vast amount of electronics. The PCB layout team at the particle accelerator thus work with a huge array of parts, for which of course they create KiCad libraries. Now the folks at CERN have made those libraries available as open source, so you can benefit from their work.

The libraries themselves can be found in a GitLab repository, and at the moment are offered only for KiCad version 9.x. We tried installing it in our KiCad 10.0 installation and it refused complaining of a missing JSON file, but we’re assuming that with more time and effort we could have made it happen. We’re told official 10.x compatibility is on the way.

Browsing the repository shows what a multiplicity of parts are included, so we can see this becoming a standard install for many people and the CERN footprints turning up in many projects featured here.

Thanks [Daniel] for the tip!

hackaday.com/2026/05/12/anothe…

Manifesti, e "costituzioni" sono fanfaronate di chi essendosi arricchito vuole anche sentirsi importante. E come sempre non c'è carenza di cantori che diano a questi ignoranti una dignità culturale.
Da oggi, lo script dell'episodio su dk.dataknightmare.eu!

dk.dataknightmare.eu/dk-10x30-…

dataKnightmare Archive

2026-05-11 09:00:00

DK 10x30 - Fanfaroni e cantori

Ascolta l'episodio su Spreaker.com

Prima di tutto una notiziola di servizio. Dopo anni mi sono deciso a mettere online gli script di DataKnightmare. C'è voluto un po', per trovare un software e un provider che dipendessero il minimo possibile dagli Stati Uniti. Soprattutto se siete come me e, se non siete incazzati, l'inutilità di tutto vi fa perdere d'animo. Non esattamente l'atteggiamento per un marketing vincente.

Per fortuna c'è Elena Rossini, che si è posta lo stesso problema e ha condiviso con me la sua soluzione. Quindi, da oggi, se DataKnightmare ha finalmente una casa testuale su dk.dataknightmare.eu, lo dobbiamo anche a Elena. Per ora ho caricato due stagioni in inglese e l'ultima in italiano. Ci vorrà un po', ma non altri dieci anni.

Veniamo a noi. Nel rumore infernale delle novità inutili che escono ogni quarto d'ora, mi è sembrato di cogliere qualcosa di interessante.

Avrete letto e straletto del cosiddetto "manifesto di Palantir", quella ventina di punti su Twitter che riassumono il libro di Alex Karp, CEO di Palantir. E avrete letto e straletto della cosiddetta "intervista a Claude" fatta nientemeno che da Walter Veltroni sul Corriere.

Prima che smettiate di ascoltare vi dico subito che non ho nessuna intenzione di entrare nel dettaglio dell'una né dell'altra. I tweet di Palantir li ho letti di sfuggita, e l'intervista di Veltroni, qualsiasi cosa contenga, non la valuto il tempo che mi ci vorrebbe per leggerla.

E quindi?

E quindi voglio parlare non dell'una o dell'altra cosa, perché sono chiaramente due stupidate, ma di quello che rappresentano, che invece secondo me è interessante.

Partiamo da lontano.

La mia generazione ha portato l'informatica in azienda. Siccome non ho combattuto a Waterloo, l'automazione in azienda c'era già, ma è la mia generazione che ha visto sparire macchine per scrivere e fax e arrivare prima Wordstar, Word e poi tutto il cucuzzaro.

Sono stati decenni tumultuosi durante i quali è stato digitalizzato tutto il digitalizzabile, alcune volte bene, altre così così, altre ancora, citando René Ferretti, a cazzo di cane.

È stato un periodo in cui ognuno ha sognato una propria versione della mitologica "organizzazione piatta" su cui le varie business school scrivevano interi scaffali di trattati.

Ma il punto è che un'organizzazione non è una struttura tecnologica. È una struttura socio-tecnica complessa, in cui la tecnologia gioca una parte. Il risultato è che il semplice arrivo di una tecnologia non determina cambiamenti automatici nei processi e nella struttura sociale dell'organizzazione, per via delle interazioni e delle retroazioni fra tutte le componenti del sistema.

Detto in termini più diretti: qualsiasi cosa ne pensino i tecnologi, non ci sono soluzioni esclusivamente tecnologiche ai problemi di un sistema socio-tecnico.

Una delle dimostrazioni più lampanti può essere per esempio "il superamento della carta", tema sul quale personalmente ho speso molti anni e molto sangue. Credo che possiamo essere tutti d'accordo sul fatto che non c'è mai stata tanta carta negli uffici da quando i documenti sono diventati digitali.

E siccome i documenti sono diventati digitali, ne esistono innumerevoli versioni, tutte sottilmente incompatibili tra loro, che continuano la loro vita indipendente in diverse parti dell'organizzazione.

Per fare un esempio semplice, una volta esisteva la carta intestata (spoiler alert, esiste ancora, ma solo per i contratti firmati dai megadirettori); oggi ogni singola sede locale, e ogni ufficio dentro quella, ha la propria versione "ufficiale" della carta intestata, con una specifica versione del logo, diversa da tutte le altre.

Se invece vi sentite troppo tecnologici per la carta intestata, possiamo parlare di processi, software, API e della relativa documentazione, di cui esistono tante versioni quanti sono i gruppi di developer.

Ogni incompatibilità che emerge durante un progetto viene risolta ad hoc, e a volte documentata, dai diversi gruppi che devono collaborare, con il solo risultato che alla fine esisterà un'altra versione in più del codice, e a volte anche della documentazione. E non venitemi a raccontare che il vostro Confluence o il vostro github sono in ordine.

Quello che è successo con i documenti è successo con tutto, ovviamente. Processi, mansioni, gerarchie.

La questione della gerarchia è interessante. Dicevamo prima che tutti hanno sognato una propria versione della mitologica "organizzazione piatta" che le business school ci assicuravano essere il futuro.

Per me e per quelli come me, organizzazione piatta significava un vertice che avrebbe dettato le linee strategiche, e subito sotto una linea di operativi ad altissima competenza con completa autonomia, eliminando ogni intromissione del top management nelle decisioni tecniche e liberandosi dell'inutile terzo del middle management.

Per il middle management, "organizazione piatta" significava automatizzare o esternalizzare, ma comunque eliminare l'inutile terzo degli operativi, con la loro fissazione di avere obiezioni tecniche alle direttive strategiche del vertice e alle loro interpretazioni da parte del middle management.

Per i vertici, "organizzazione piatta" significava eliminare l'inutile terzo degli operativi e interfacciarsi esclusivamente con il middle management, così da superare finalmente il bisogno di considerare i cosiddetti "dettagli tecnici".

Se vi guardate attorno oggi, non è difficile capire chi ha vinto. I vertici sono ancora tutti lì, e il middle management ha ranghi più pieni che mai. L'appiattimento delle organizzazioni, se c'è stato, ha significato estromettere ed esternalizzare perlopiù le competenze tecniche.

Allo stesso tempo, c'è stata una evoluzione notevole nei ruoli apicali. Con l'avvento del venture capital dagli anni 2000 in poi, le figure apicali sono passate dall'essere figure gestionali ad essere figure sempre più performative. In nessun ruolo questo è più evidente che nel ruolo del CEO. Oggi, il CEO è sopratuttto qualcuno in grado di intessere una narrazione convincente della propria visione del futuro, per poter raccogliere, sul mercato o da investitori privati, i finanziamenti necessari a costruirlo.

Che quel futuro abbia tecnicamente o economicamente senso, che sia perfino possibile, o che abbia una qualche relazione col futuro raccontato nell'ultimo esercizio, non ha alcuna importanza.

Quello che conta è che la figura del CEO, e la narrazione che propone per questo semestre, continui a ispirare la fiducia degli investitori. Null'altro conta.

Il CEO oggi non deve essere capace di "fare", e nemmeno più di dirigere. Deve solo saper convincere. Incessamente, cambiando storia ogni volta che serve senza battere ciglio. Le sue qualità distintive sono la testardaggine e un'inflazionato senso del proprio valore, che purtroppo sono caratteristiche distintive anche del narcisista patologico.

Pensate a Zuckerberg, partito con l'idea geniale di fare un social dove i suoi compagni di corso potevano votare la scopabilità delle studentesse, fortuna che poi è arrivata Sheryl Sandberg a fargli fare davvero i soldi; poi ha cercato di reinventare il denaro (ricordate Libra?), poi ha venduto il metaverso, e adesso è in coda al carrozzone dell'AI dopo il disastroso esordio con chiusura in 72 ore di Galactica.

Pensate a Musk, che ha l'immaginario di un adolescente mediocre nel 1975, e alle puttanatein serie su macchine a guida autonoma, colonizzazione di Marte, e megacostellazioni di satelliti.

Pensate al migliore di tutti, Sam Altman, un altro che scrive un blog e sembra che Giovanni Evangelista abbia dato alle stampe una versione aggiornata. Altman ha imbonito l'intero mondo del venture capital con l'unica promessa di bruciare tutti i soldi degli investitori per poi raccoglierne ancora di più.

Da una fanfaronata alla successiva, tutti loro pensano che il proprio successo non sia frutto di fortuna, conoscenze, contratti pubblici e monopolio, ma del loro essere speciali e visionari. Quando Taleb ci insegna che mentre un buon successo si spiega con capacità e impegno, un successo travolgente si spiega con la varianza.

Non divaghiamo. Oggi un CEO del digitale deve poter sentenziare:

“Guidiamo l’evoluzione sinergica del nostro ecosistema valoriale attraverso un approccio olistico e data-driven, abilitando paradigmi scalabili di innovazione sostenibile orientata alla centralità del cambiamento.”

e farlo con un'aria di profonda convinzione. È ovviamente solo aria fritta, ma chi si mette a ridere o pensa che la frase non abbia alcun senso, non sarà mai un C-level, e non otterrà mai un'intervista.

Di pari passo con la virata performativa di CEO e founder, anche il sistema mediatico si è adattato. Con fallimenti, ristrutturazioni, acquisizioni, oggi i media sono, con poche eccezioni, marketing esternalizzato in mano agli stessi industriali che i media dovrebbero tenere sotto indagine. Intendiamoci, ogni potente ha sempre avuto sicofanti e agiografi in ogni testata, ma oggi ai media viene richiesto di limitarsi a dare risonanza alla narrazione aziendale.

A questo ha contribuito, e non poco, anche una certa lettura mitica, molto statunitense, del settore digitale e dei suoi attori. Dai "cowboy della tastiera" di William Gibson, agli "eroi della frontiera digitale" di Steven Levy, si è fatto ogni sforzo per riproporre il mito fondativo della frontiera, con tutto il suo bagaglio tossico, in salsa digitale.

Il risultato è che oggi sono gli stessi protagonisti a vedere se stessi in termini mitici. E d'altronde non potrebbe essere altrimenti, nessuno vuole pensare di essere soltanto un fortunato raccontatore di favolette semestrali, per quanto bravo.

No, sono invece tutti "visionari", "costruttori del futuro" quando non addirittura "rivoluzionari", ovviamente nel senso capitalistico del termine, ovvero distruttori di industrie e comunità a esclusivo vantaggio proprio e dei propri investitori.

Questo ci porta finalmente a Palantir e a Karp. Che non si accontenta di aver fondato un'azienda che si ingrassa di commesse militari, perché ai capitalisti lo Stato piace ridotto ai minimi termini tranne che come cliente, ma propone la propria immagine mitica di difensore di un occidente convenientemente assediato soltanto da quei problemi che i suoi prodotti dichiarano di affrontare.

E non, per dire, da una disparità economica e sociale senza precedenti, da mutamenti sociali e climatici globali e da una casta di miliardari esentasse in fregola oligarchica. Di nuovo, assistiamo alle fanfaronate di qualcuno che non ha un'idea originale in testa e per questo ha fatto fortuna.

Che Karp, come tutti gli altri miliardari amichetti suoi, ritenga di avere una "visione" da comunicare al pubblico, al di là della trimestrale di cassa, non stupisce. E non stupisce nemmeno che ribadisca i temi del libro in una serie di tweet, forse per compensare vendite meno che travolgenti: tutti, alla fine, vogliono essere visti.

Ma se si gratta appena la superficie delle narrazioni dei CEO, ci si accorge che la Silicon Valley produce soltanto variazioni sul tema di chi l'ha creata e finanziata da sempre: il Pentagono della Guerra Fredda.

Leggete fin che volete Amodei, Altman, Karp, Zuckerberg, Thiel. Ci troverete sempre supremazia statunitense attraverso la tecnologia, esportazione dei valori del capitalismo a stelle e strisce, controllo sociale, contenimento dello sviluppo di qualsiasi potenza concorrente sulla placca euroasiatica.

Roba che non è cambiata di una virgola dal 1946, scritta e sistematizzata da fior di cervelli come Bush (Vannevar, consigliere scientifico di Roosevelt e Truman, omonimo ma non parente dei successivi presidenti George Bush e George Bush il Minore), Kissinger, Brzezinski, Cheney, gente che ha guidato la politica statunitense per decenni mentre i presidenti di turno facevano i fighi in TV recitando le parole chiave di stagione.

Questo non significa che i deliri oligarchici di Karp e compagnia siano innocui, tutt'altro. Ma non sono geni del male. Sono solo attori che, fuori dal teatro, credono ancora di essere Giulio Cesare.

Questi finti campioni della libera iniziativa con i soldi pubblici questo autonominati "inventori del futuro", stanno solo scimmiottando le parole chiave di chi li ha fatti nascere e li mantiene.

Ora, il potere attira servi e sicofanti, l'ho già detto. Ma non si accontenta di quelli, che in fondo disprezza. Ogni potente, e a maggior ragione ogni fanfarone arricchito, ha bisogno di sentirsi validato da qualcuno di cui segretamente invidia la statura, sociale o culturale.

Ed ecco arrivare il cantore. Quello che nel XX secolo si chiamava "intellettuale organico", il cui compito è di usare la propria cultura per dare un po' di densità e di smalto alle narrazioni del potente di turno. Il cantore è più astuto del sicofante, e si può perfino permettere un atteggiamento superficialmente critico, perché il suo ruolo non è confermare punto per punto la narrazione del potente, quello lo fanno già servi e sicofanti, ma validarla dandola completamente per scontata, e distrarre l'attenzione dai problemi con una discussione molto colta su qualche dettaglio insignificante.

Così, mentre gli AI bro imboniscono gli investitori con favole di macchine senzienti e di eliminazione dei lavoratori, pardon, superamento del lavoro, il cantore non si abbassa a entrare nel merito, ma intervista l'intelligenza artificiale. Da Veltroni mi sarei aspettato, se non più dignità, almeno più tempismo. L'intervista con l'Intelligenza Artificiale fa tanto autunno-inverno 2023.

Il cantore è più subdolo del sicofante, perché non si spende pro o contro. Si limita a includere la narrazione del potente nel dibattito "colto".

Se il potente di turno parla di nucleare di nuova generazione, il servo griderà ai quattro venti che il solare e l'eolico sono superati, il sicofante farà notare che l'area verde attorno alla centrale è l'ideale per un picnic con la famiglia.

Il cantore, invece, si mette a discorrere di come le torri di raffreddamento possano rappresentare l'evoluzione dei cipressi del Carducci che "van da San Vito in duplice filar".

Il cantore del digitale, con tutta la sua cultura, non ha niente da dire di specifico, ma lo dice con parole ricercate e citazioni altisonanti. Il suo compito non è discutere o confutare la narrazione del potente, ma tagliare le gambe a ogni dibattito serio dandola per scontata e costruendo una apparente discussione dotta su dettagli completamente marginali.

E in questo, Veltroni ha fatto il suo lavoro. Il fatto stesso di "intervistare" (si sentono le virgolette?) un generatore automatico di testo, e scegliere di farlo su questioni che sarebbero profonde se l'interlocutore fosse un essere umano e non uno specchio retorico, è quanto di più devastante si possa mettere in campo a supporto dei deliri millenaristici dei fanfaroni del digitale.

Se ha ancora un senso l'intellettuale pubblico, il pezzo di Veltroni è il completo tradimento di quel ruolo, l'asservimento della cultura alle ragioni di chi cultura non ne ha nessuna, ma ha soldi a valanghe.

Mentre da sempre chi ha competenza sul tema fa notare quanto sia dannoso, e quali interessi sostenga, antropomorfizzare una tecnologia come la cosiddetta Intelligenza Artificiale, Veltroni arriva bel bello e l'Intelligenza Artificiale te la intervista sul senso dell'esistenza. Non importa che non abbia nulla da dire al riguardo, perché non ce l'ha. Importa solo che un generatore di testo improvvisamente passa per qualcosa con cui si può addirittura "parlare" del senso della vita.

Veltroni avrebbe potuto fare davvero l'intellettuale, e parlare di che senso abbia un'Europa che vuole rincorrere gli Stati Uniti in una bolla speculativa. Avrebbe potuto parlare dei problemi dell'uso dell'Intelligenza Artificiale nelle professioni, nei media, nell'istruzione.

Avrebbe perfino potuto fare l'intellettuale di sinistra e parlare di oligopoli e rendite di posizione, di tecnofeudalesimo, del ruolo politico dell'Intelligenza Artificiale nella demolizione del potere contrattuale del lavoro.

Avrebbe potuto parlare di tutto questo e di molto altro.

Invece ha scelto di fare il cantore dei fanfaroni arricchiti e, facendolo, credo abbia stabilito quale sia il suo posto nella gerarchia in cui Sciascia annoverava uomini, mezz'uomini, ominicchi, pigliainculo e quaqquaraqquà.

Io un'idea ce l'ho.

DK 10x30 - Fanfaroni e cantori

^{Runtime Radio (Spreaker)}

With International Anti-Ransomware Day taking place on May 12, Kaspersky presents its annual report on the evolving global and regional ransomware cyberthreat landscape.

Ransomware remains one of the most persistent and adaptive cyberthreats. In 2026:

• New families continue to emerge, adopting post-quantum cryptography ciphers.
• As ransom payments drop, some groups implement encryptionless extortion attacks.
• In a constantly changing ecosystem of threat actors, initial access brokers maintain a relevant role in this market, showing increased focus on access to RDWeb as the preferred method of remote access.

Ransomware attacks decline but remain a major threat

According to Kaspersky Security Network, the share of organizations affected by ransomware decreased in 2025 across all regions compared to 2024.

Percentage of organizations affected by ransomware attacks by region, 2025 (download)

Despite the formal decrease, organizations across all sectors continue to face a high likelihood of attack, as ransomware operators refine their tactics and scale their operations with increasing efficiency. Kaspersky and VDC Research have found that in the manufacturing sector alone, ransomware attacks may have caused over $18 billion in losses in the first three quarters of the year.

The continued rise of EDR killers and defense evasion tooling

In 2026, ransomware operators increasingly prioritize neutralizing endpoint defenses before executing their payloads. Tools commonly referred to as “EDR killers” have become a standard component of attack playbooks. This reflects a continuing trend toward more deliberate and methodical intrusions.

Attackers attempt to terminate security processes and disable monitoring agents, often by exploiting trusted components such as signed drivers. This technique is called Bring Your Own Vulnerable Driver (BYOVD) and allows adversaries to blend into legitimate system activity while gradually degrading defensive visibility.

Thus, evasion is no longer an opportunistic step but a planned and repeatable phase of the attack lifecycle. As a result, organizations are increasingly challenged not just to detect ransomware but also to maintain control in environments where security controls themselves are actively targeted.

The appearance of new families adopting post-quantum cryptography

We predicted that quantum-resistant ransomware would appear in 2025. Looking back at the previous year, we see that advanced ransomware groups indeed started using post-quantum cryptography as quantum computing evolved. The encryption techniques used by this quantum-proof ransomware could be used to resist decryption attempts from both classical and quantum computers, making it nearly impossible for victims to decrypt their data without having to pay a ransom.

One example is the appearance of the PE32 ransomware family (link in Russian); it leverages the cutting-edge ML-KEM (Module-Lattice-Based Key-Encapsulation Mechanism) standard to secure its AES keys. This specific cryptographic framework was recently selected by NIST as the primary standard for post-quantum defense.

Within the PE32 ransomware architecture, this is realized through the Kyber1024 algorithm, a robust mechanism providing Level 5 security, roughly equivalent in strength to AES-256. Its primary function is the secure generation and transmission of shared secrets between parties, specifically engineered to withstand future quantum computing attacks. This shift toward post-quantum readiness is part of a broader industry trend; for instance, TLS 1.3 and QUIC protocols have already adopted the X25519Kyber768 hybrid model, which fuses classical encryption with quantum-resistant security.

The shift to encryptionless extortion

In 2025, the share of ransoms paid dropped to 28%. As a response to this, one of the developments in the 2026 landscape is the growing prevalence of extortion incidents in which no file encryption takes place at all. Instead, attackers leave out the “ware” in “ransomware” and focus on extracting sensitive data and leveraging the threat of public disclosure as their primary means of extortion. ShinyHunters is an excellent example of such a group, using a data leak site to publicize its victims.

By avoiding encryption, attackers may aim at reducing the likelihood of immediate detection, shortening the duration of the attack, and eliminating dependencies on stable encryption routines. Often, this model is used alongside traditional tactics in so-called double extortion schemes, but an increasing number of campaigns rely exclusively on data theft.

For victims, this shift fundamentally changes the nature of the risk. While backups remain effective against encryption-based disruption, they provide no protection against data exposure, regulatory consequences, and reputational damage. Ransomware is therefore evolving from a business continuity issue into a broader data security and compliance challenge.

Industrialization of initial access (Access-as-a-Service)

The ransomware ecosystem continues to evolve toward a highly industrialized and specialized model, with initial access remaining as one of its most critical components. In 2026, many ransomware operators keep relying on IABs (initial access brokers), a network of intermediaries who supply pre-compromised access to corporate environments, aiming to no longer perform full intrusions themselves.

This “access-as-a-service” model is fueled by credential theft operations, and the widespread availability of compromised accounts harvested through infostealers and phishing campaigns.

The primary access vectors offered for sale have not changed: RDP, VPN, and RDWeb are still the top access vectors. Consequently, remote access infrastructure remains the primary attack surface for initial access sales. In response to the measures against public exposure of RDP access points to the internet, attackers are now targeting RDWeb portals, which are frequently vulnerable and occasionally inadequately safeguarded.

The result is a threat landscape where unauthorized access is increasingly commoditized, and the barrier to launching ransomware attacks declines. This means that preventing initial compromise is only part of the challenge; equal emphasis must be placed on detecting misuse of legitimate credentials and limiting lateral movement within already-breached environments.

Ransomware developments on the dark web

Telegram channels and underground forums increasingly function as platforms for the distribution and sale of compromised datasets and access credentials including those that were obtained as a result of ransomware attacks.

Advertisements posted on these resources typically include the nature of the access, a description of the exfiltrated or compromised data, price terms, and contact information for prospective buyers. In addition, some malicious actors mention their collaboration with other ransomware groups. Lesser-known gangs can use this name-dropping to promote themselves

Multiple threat actors not related to ransomware groups distribute datasets downloaded from ransomware blogs on underground forums and Telegram. By re-publishing download links and files, they spread compromised data as well as information on the ransomware attack within the community.

The ransomware itself is also sold or offered for subscription on the dark web platforms. The sellers underscore the uniqueness of their malware, as well as its encryption and defense evasion features.

Law enforcement actions

Law enforcement agencies are actively shutting down dark web platforms and ransomware data leak sites. A major underground forum, RAMP, which also functioned as a platform for threat actors to advertise their ransomware services and publish service‑related updates, was seized by authorities in January 2026. Another underground forum, LeakBase, where malicious actors distributed exfiltrated and compromised data, was seized in March 2026. In 2025, law enforcement agencies seized well-known forums like Nulled, Cracked, and XSS. Also in 2025, the DLSs of BlackSuit and 8Base ransomware groups were seized. These takedowns cause inconvenience to ransomware coordination, specifically for initial access brokers and affiliates, though similar forums are expected to fill the void over time.

Top ransomware groups in 2025

RansomHub’s sudden dormancy in 2025 marked a shift, and Qilin became the dominant player from Q2 onward. According to Kaspersky research, Qilin was the most active group executing targeted attacks in 2025.

Each group’s share of victims according to its data leak site (DLS) as a percentage of all reported victims of all groups during the period under review (download)

Qilin stands out as one of the fastest-growig and dominant RaaS platforms. Its combination of high-volume operations and structured affiliate model positions it as a central player in the current ecosystem.

Clop, the second most active group in 2025, is distinguished through its large-scale, supply-chain-style attacks, exploiting widely used file transfer and enterprise software to compromise hundreds of victims simultaneously. This one-to-many approach sets it apart from more traditional, single-target campaigns.

Third place is occupied by Akira, which remains notable for its consistency and operational stability, maintaining a steady stream of victims without major disruption. Its ability to sustain activity over time makes it one of the most reliable indicators of baseline ransomware threat levels.

Although no longer active, RansomHub stands out for its rapid rise and equally rapid disappearance in 2025, highlighting the volatility of the RaaS market. Its shutdown created a vacuum that significantly reshaped affiliate distribution across other groups.

DragonForce is also notable – not just for its own operations, but for its broader influence within the ransomware ecosystem, including reported involvement in infrastructure conflicts and possible links to the disruption of competing groups. Thus, the group claims that RansomHub “has moved to their infrastructure.” This positions it as more than just an operator and potentially an ecosystem-level actor.

New actors in 2026

While emerging actors generally operate on a smaller scale, they provide insight into the continuous churn and low barrier to entry within the ransomware ecosystem.

The Gentlemen group caught our attention in early 2026, as they managed to attack a significant number of victims over a short time. This actor is also notable for reflecting a broader shift toward professionalization and controlled operations within the ransomware ecosystem. Unlike many emerging groups that rely on opportunistic attacks and inconsistent leak activity, The Gentlemen demonstrate a more deliberate approach: structured intrusion workflows, selective targeting, and measured communication with victims. This signals a move away from chaotic, high-noise campaigns toward predictable, business-like execution models that are easier to scale and harder to disrupt. Their TTPs include the massive exploitation of hardware very common on big corporations, such as FortiOS/FortiProxy, SonicWall VPN, and Cisco ASA appliances. The group might be comprised of professional cybercriminals who left other prominent groups.

The group is also notable for its emphasis on data-centric extortion strategies, often prioritizing exfiltration and leverage over purely disruptive encryption. This aligns with one of the defining trends of 2026: ransomware evolving into a form of data breach monetization rather than just system denial. By focusing on controlled pressure and reputational risk instead of immediate operational damage, The Gentlemen exemplify how attackers are adapting to lower ransom payment rates and improved backup practices among victims.
Some other groups to take note of in 2026:

• Devman appears to be an emerging actor with limited but growing activity, likely leveraging existing tooling rather than developing custom capabilities.
• MintEye hasn’t been very active yet, with just five known victims, suggesting opportunistic campaigns without a consistent operational tempo.
• DireWolf is associated with small-scale, targeted attacks, though its overall footprint remains relatively limited compared to larger RaaS groups.
• NightSpire demonstrates characteristics of an amateur group, such as mistakes during its operations, uncommon communication channels with the victims, and sometimes giving them insufficient time to pay up. Although they both encrypt and leak data, they prioritize publication rather than encryption.
• Vect shows low-volume activity. It is yet unclear whether they use a completely new codebase or are rather a rebrand of an existing group.
• Tengu is a less prominent actor, with limited public reporting and no clear distinguishing tactics beyond standard extortion models.
• Kazu appears to be created by ransomware operators previously engaged with multiple other groups. As of now, they don’t stand out for scale or technique.

Although there is little to say about these groups at the time of writing this report, each of them may be equally likely to disappear from the threat landscape or grow into a prominent threat. That’s why it’s important to track them from their early days. Moreover, collectively, these groups illustrate how dynamic the ransomware landscape is, with new entrants constantly replenishing it.

Conclusion and protection recommendations

Despite the growing effort by law enforcement agencies across the globe to seize and disrupt dark web platforms and threat actor infrastructures, ransomware operations remain stable, with new groups quickly taking the place of those who went silent. In 2026, we see a shift towards encryptionless extortion, with data leaks increasingly becoming the main threat to target organizations. At the same time, data encryption is also upgrading to the next level with the emergence of post-quantum ransomware.

To resist the evolving threat, Kaspersky recommends organizations:

Prioritize proactive prevention through patching and vulnerability management. Many ransomware attacks exploit unpatched systems, so organizations should implement automated patch management tools to ensure timely updates for operating systems, software, and drivers. For Windows environments, enabling Microsoft’s Vulnerable Driver Blocklist is critical to thwarting BYOVD attacks. Regularly scan for vulnerabilities and prioritize high-severity flaws, especially in widely used software.

Strengthen remote access: RDP and RDWeb connections should never be directly exposed to the internet, only through VPN or ZTNA (Zero Trust Network Access). It’s highly recommended to adopt multi-factor authentication on everything; the architecture may require continuous authentication for access, as one valid credential captured is enough to cause a breach. Monitoring the underground for stolen employee credentials is essential. Audit open ports across the entire attack surface. The adoption of the “Principle of Least Privilege” (PoLP), where users, systems, or processes are granted only the minimum access rights, such as read, write, or execute permissions, necessary to perform their specific job functions, is highly recommended.

Strengthen endpoint and network security with advanced detection and segmentation. Deploy robust endpoint detection and response solutions such as Kaspersky NEXT EDR to monitor for suspicious activity like driver loading or process termination. Network segmentation is equally important. Limit lateral movement by isolating critical systems and using firewalls to restrict traffic. Complete and immediate offboarding for employees is necessary as well as periodic permission reviews, with automatic revocation of unused access. Sessions with complete logging for privileged accounts are more than necessary. Monitoring the traffic divergence to new sites or even to legitimate endpoints can help the defenders to spot a new insider threat.

Invest in backups, training, and incident response planning. Maintain offline or immutable backups that are tested regularly to ensure rapid recovery without paying a ransom. Backups should cover critical data and systems and be stored in air-gapped environments to resist encryption or deletion. User education is essential to combatting phishing, which remains one of the top attack vectors. Conduct simulated phishing exercises and train employees to recognize AI-crafted emails. Kaspersky Global Emergency Response Team (GERT) can help develop and test an incident response plan to minimize potential downtime and costs.

The recommendation to avoid paying a ransom remains robust, especially given the risk of unavailable keys due to dismantled infrastructure, affiliate chaos, or malicious intent. By investing in backups, incident response, and preventive measures like patching and training, organizations can avoid funding criminals and mitigate the impact.

Kaspersky also offers free decryptors for certain ransomware families. If you get hit by ransomware, check to see if there’s a decryptor available for the ransomware family used against you.

securelist.com/state-of-ransom…

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)

hackaday.com/2026/05/11/revers…

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.

hackaday.com/2026/05/11/the-wa…

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.

hackaday.com/2026/05/11/honda-…

Guess what time it is– that’s right, clock time! It’s always clock time, and when it’s clock time at Hackaday the weirder the better. So, how about a water clock that’s not actually a water clock? The water here has nothing to do with timekeeping, but is what’s driving the display. Fair to say that [Strange Inventions] is living up to the name of his YouTube channel.

You can get the idea from the header image: each digit is formed by a fifteen-segment display made up of glass bottles. A stepper-driven peristaltic pump and some membrane-pump boosters fills the bottles as needed with dyed water, while emptying is accomplished simply by having a servo dump the water into a trough. It’s an interesting, albeit messy, way to generate a display.

It wasn’t the original idea– well, the bottles were the original concept, but flipping them was not. Dumping the bottles has the advantage of not needing oodles of pumps or taking five minutes to sequentially fill and drain the bottles at each digit. The linkage to get the servo to flip all nine bottles in one go took some troubleshooting– we can relate, since the physical half of such projects usually is the hard part– but after many modifications the 3D printed mechanism worked, and we think the results are worth it.

If you’re looking for the other kind of water clock, we featured one of those before, too. This one is also of ancient style, but makes use of modern electronics. It occurs to us that if one was really, really ambitious, they could expand this [Strange] project into a very damp flip-dot style display.

youtube.com/embed/YKB5-sgexI0?…

hackaday.com/2026/05/11/its-a-…

A computer the size of a credit card is nothing new. There have been many single-board computers following the familiar dimensions. [Krauseler]’s credit card computer is different, though. It packs an ESP32-C3, e-paper display, NFC reader, and, incredibly, a Li-Po battery into a credit card form factor in three dimensions rather than two. That’s right, this computer is only 1mm thick.

To ensure perfect compliance with the form factor, the enclosure, if that’s what it can be called, is a real NFC card with the middle cut out to take the electronics. The PCB is flexible, and the battery is the thinnest available. The e-paper display is an ultra-thin, flexible variant. A display connector would have been too thick, so a very fine wire-and-solder job was required.

On its own, an ESP32-C3-based computer with an NFC reader and an e-paper display would be a pretty cool project, depending on what software was on it. This one, however, redefines the term “credit card-sized.”

It’s not the first piece of electronics we’ve seen that tries for the full credit card format, but it’s certainly the only one so far to slim down to 1 millimetre.

Thanks [Joey] for the tip!

hackaday.com/2026/05/11/this-c…

Humanoid robots are a thing now, and here’s an interesting research project that explores using one as a form of haptic media. Specifically, using a humanoid robot to move a chair while one plays a VR driving simulator.

Here’s how it works: a Unitree G1 robot sits behind a player’s chair and grasps it with its hands. Spherical markers on the chair help the robot’s depth camera know the chair’s position, and real-time G-force signals fed from the simulator (Assetto Corsa, running on PC) tell the robot how much and in what direction to shift the chair to match in-simulator events.

While a humanoid robot (especially one equipped with articulated, human-like hands) makes for an awfully expensive force feedback chair, this approach is interesting because it specifically explores using an already-existing humanoid robot as a general-purpose device. It sits in a chair, looks with its camera, grasps with its hands, and moves the player’s chair in response to game events; no hardware modifications required.

So how well does it work? Pretty well, apparently! Participants found the synchronized motion feedback accurate and highly enjoyable, although it does seem like there were some rough edges. Some testers reported that the sustained motion and constant vibration were tiring, and in some cases seemed to worsen VR sickness.

Still, using a robot in this way seems to be a conceptual success and showcases the potential of humanoid robots as flexible, general-purpose devices. We’ve seen a robot used to provide interactive force feedback in VR before, but a driving simulator makes for a pretty fun demonstration.

The video is embedded below, and for more information, check out the team’s research paper.

youtube.com/embed/ggsCDhQv6Hg?…

hackaday.com/2026/05/11/want-d…

Seminario di studi presso l’Isituto comprensivo di Anguillara Sabazia

dicorinto.it/formazione/progag…

When most people think about vacuum tubes, they picture big glass bottles glowing inside antique radios or early computers. History often treats tubes as a dead-end technology that was suddenly swept away by the transistor in the 1950s. But the reality is much more interesting. Vacuum tube technology did not simply stop evolving when the transistor appeared. In fact, some of the most sophisticated and technically impressive tube designs emerged after the transistor had already been invented.

During the final decades of mainstream tube development, manufacturers pushed the technology in remarkable directions. Tubes became smaller, faster, quieter, more rugged, and more specialized. Designers experimented with exotic geometries, ceramic construction, metal envelopes, ultra-high-frequency operation, and even hybrid tube-semiconductor systems. Devices such as acorn tubes, lighthouse tubes, compactrons, and nuvistors represented a last gasp of thermionic electronics.

Ironically, many of these innovations arrived just as solid-state electronics were becoming commercially practical. Vacuum tubes were improving rapidly right up until the market abandoned them.

The Pressure to Improve

By the 1930s and 1940s, vacuum tubes dominated electronics. Radios, radar systems, military communications, industrial controls, and the first digital computers all depended on them. But everyone was painfully aware of their problems.

Traditional tubes were fragile, generated heat, consumed significant power, and suffered from limitations at high frequencies. Internal lead lengths created parasitic inductance and capacitance. At radio frequencies and especially microwave frequencies, those unwanted effects made design difficult.

Military requirements during World War II accelerated development dramatically. Radar systems needed tubes capable of operating at VHF, UHF, and microwave frequencies. Vehicle equipment required devices that could withstand punishment. Computers with tubes suffered from frequent failures, took up entire rooms, and needed special cooling equipment, often bigger than the computer. These pressures drove tube designers into an intense period of innovation.

Acorn Tubes: Tiny Tubes for High Frequencies

One of the earliest major departures from conventional tube geometry was the acorn tube. Developed in the 1930s by RCA, the acorn tube got its name from its distinctive shape, which resembled an acorn with wire leads protruding from the base and sides. Unlike ordinary tubes, where the internal elements had relatively long leads, the acorn design minimized lead length to reduce parasitic capacitance and inductance. At high frequencies, this reduction was crucial.

One famous example was the 955 acorn triode. These tubes found use in experimental television receivers, military radios, and laboratory equipment. Acorn tubes also reflected an important trend in late tube development: engineers were increasingly treating tubes not merely as amplifying devices, but as microwave structures requiring careful electromagnetic design.

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The Lighthouse Tube

If acorn tubes were specialized, lighthouse tubes were positively futuristic. Lighthouse tubes abandoned the classic cylindrical glass form almost entirely. Instead, they used stacked disk-like electrodes arranged in a compact coaxial structure. The resulting geometry minimized transit times and parasitic reactances, allowing operation into microwave frequencies.

The tubes vaguely resembled a lighthouse tower. These tubes became essential in radar systems during World War II and the early Cold War period. Some lighthouse designs could operate in the gigahertz range, something impossible for conventional receiving tubes.

Their construction also introduced new manufacturing techniques. Many used ceramic and metal rather than large glass envelopes. This improved heat resistance and mechanical stability while reducing losses at high frequencies.
In many ways, lighthouse tubes represented the transition from classic vacuum tubes and true microwave devices like klystrons and traveling-wave tubes.

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Metal Tubes and Ruggedization

Another path of tube evolution focused on durability and compactness. Early tubes used fragile glass envelopes that were easily broken and susceptible to microphonics and vibration. During the 1930s, manufacturers introduced all-metal tube designs. These tubes replaced the glass envelope with a metal shell, improving shielding and mechanical ruggedness.

Metal tubes were particularly attractive for military and automotive applications. Shielding reduced interference, while the smaller physical size allowed more compact equipment layouts.

Hybrid glass-metal constructions also became common. Engineers experimented constantly with new materials and packaging approaches to reduce noise, improve reliability, and extend tube lifespan.

Subminiature Tubes

One of the most impressive developments was the subminiature tube. These tiny devices often looked more like oversized resistors than conventional tubes. Some were less than an inch long and designed to be soldered directly into circuits rather than plugged into sockets.

Subminiature tubes emerged largely from military demands during and after World War II. Proximity fuzes for artillery shells required electronics small enough to survive being fired from a cannon. Traditional tubes would simply shatter under the acceleration.

The resulting ruggedized miniature tubes were shock-resistant and compact enough for portable military electronics. After the war, subminiature tubes appeared in hearing aids, portable radios, test instruments, and early miniaturized computers.

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The Nuvistor: The Ultimate Receiving Tube

One of the most interesting late-stage vacuum tube was the RCA Nuvistor. Introduced by RCA in 1959, the nuvistor represented an attempt to create a truly modern vacuum tube for the transistor age.

Unlike classic glass tubes, nuvistors used a compact metal-and-ceramic construction. They were extremely small, highly reliable, vibration-resistant, and capable of excellent high-frequency performance. They also exhibited very low noise characteristics. At first glance, a nuvistor hardly resembles a traditional tube at all. You could easily mistake these for some other component in a metal can.

Technically, nuvistors were excellent devices. They offered superior performance in many RF applications compared to early transistors, particularly in television tuners, instrumentation, and aerospace electronics.

High-end studio microphones also adopted nuvistors because of their low noise and desirable electrical behavior. Some audiophiles still use nuvistor-based equipment today.

But despite their capabilities, nuvistors arrived too late. Semiconductor technology was improving rapidly. Silicon transistors were becoming cheaper, more reliable, and easier to manufacture in large quantities. Integrated circuits loomed on the horizon. The nuvistor may have been the best small receiving tube ever made, but it was competing against a technology whose economics would soon become overwhelming.

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Compactrons

As semiconductor electronics advanced, tube manufacturers attempted another strategy: integration. The Compactron, introduced by General Electric in the early 1960s, combined multiple tube functions into a single envelope. A compactron might contain several triodes, pentodes, or diode sections in one package. This reduced component count, simplified wiring, and lowered manufacturing costs for television sets and other consumer electronics. Of course, tubes with multiple electrodes weren’t new. They dated back to at least 1926. However, GE’s aggressive marketing of the brand was an attempt to prevent designers from defecting to the solid-state camp.

In some sense, compactrons were the vacuum tube answer to integrated circuits. Engineers were trying to achieve greater functional density while keeping tube-based designs economically competitive. GE’s Porta-Color, the first portable color television, used 13 tubes, including 10 Compactrons. They usually have 12-pin bases and an evacuation tip at the bottom of the tube rather than at the top.

Compactrons saw widespread use in televisions, stereos, and industrial electronics during the 1960s and early 1970s. But again, semiconductor integration advanced even faster. The battle was becoming impossible to win.

Specialized Tubes Survived

Even after transistors took over consumer electronics, vacuum tubes remained important in specialized fields. Microwave tubes such as klystrons, magnetrons, and traveling-wave tubes continued to dominate high-power RF applications. Radar systems, satellite communications, particle accelerators, and broadcast transmitters all relied on advanced vacuum devices. In some areas, they still do.

A modern microwave transmitter aboard a communications satellite may still use a traveling-wave tube amplifier because tubes can handle very high frequencies and power levels efficiently.

No Instant Win

One misconception about electronics history is that the transistor immediately rendered tubes obsolete after its invention at Bell Labs in 1947. That is not what happened.

Early transistors had many limitations. They were noisy, temperature-sensitive, low-power, and expensive. Tubes often outperformed them in RF circuits, audio applications, and high-power systems well into the 1960s.

For a significant period, designers genuinely did not know which technology would dominate certain markets. Tube designers were still making substantial advances. Nuvistors and Compactrons were not desperate relics; they were serious engineering efforts intended to compete in a changing world.

Ultimately, however, semiconductors possessed overwhelming long-term advantages. Transistors required less power, generated less heat, occupied less space, and could be manufactured using scalable photolithographic processes. Once integrated circuits became practical, the economics shifted decisively. Vacuum tubes could evolve, but they could not shrink into millions of devices on a silicon chip.

The final years of vacuum tube development are often overlooked because history tends to focus on winners. Yet this period produced some of the most elegant and specialized electronic devices ever created. By the late tube era, vacuum tube manufacturing had become quite refined. Engineers could produce tubes with tightly controlled characteristics and surprisingly long operating lives.

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Some early transistorized devices still retained subminiature tubes in certain high-frequency or low-noise stages because transistors had not yet surpassed tube performance in every application. This overlap period is often forgotten today. Electronics did not instantly switch from tubes to semiconductors. For years, many systems used both. For many years, a typical ham radio transmitter, for example, would be all solid-state except for the power amplifier finals, which were often a pair of 6146 tubes.

You can, of course, make your own tubes. If you’ve had enough of making your own tubes, maybe try reproducing some of these advanced models.

hackaday.com/2026/05/11/the-va…

IT'S MONDAY, AND THIS IS DIGITAL POLITICS. I'm Mark Scott, and will be in Brussels all next week for this conference (where I'll be moderating a panel on May 20 at 11:50 CET.) If you're around and want to grab coffee, ping me here.

— Countries want to build sovereign AI infrastructure. I crunched the numbers to see how much that would actually cost.

— Digital antitrust cases were supposed to rein in the power of dominant players. But when it comes to online advertising, market power is on the rise.

— Spending on government-focused AI systems will rise 35 percent this year to over $80 billion.

Let's get started:

digitalpolitics.co/newsletter0…

Although the term ‘dry ice’ is generally used for solid CO₂, it’s much more accurate to call this ‘dry snow’, as, rather than being actual solid blocks, they are effectively snow that’s been compressed really tightly. While not really necessary for most applications of dry ice, it is possible to make blocks of actual CO₂ ice, and thus [Hyperspace Pirate], as someone with a healthy obsession with cold things had to make some of his own.

As a first step, you, of course, have to chill down CO₂ in a container, for which Mr. [Pirate] used a Joule-Thomson cryocooler, with a 15% butane, 35% propane, and 50% ethylene gas mixture. Of course, as ethylene is only easy to get if you have a lot of money to spend, you will want to make it yourself from ethanol. This involves boiling and 400°C aluminum oxide to capture the produced ethylene.

With the CO₂ pressure chamber cooled in its refrigerated bath, the process didn’t take long. After opening the pressure chamber, the results were interesting to say the least. Although there was definite ice formation along the sides that contacted the metal chamber the closest, the closer to the center, the more the CO₂ resembled the usual fluffy, compressed dry ice.

This is encouraging as it shows that it’s definitely possible to make nice ice pucks or cubes, but the method needs further refinement to get more ice and less snow.

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We feature a lot of DIY portable computers — rehash the “is that a cyberdeck” in the comments to your heart’s content — but how many of them are explicitly girly? Certainly, none of the ones that come to mind oozed the distilled femme energy of [cc] AKA [bossbratox]’s project, playfully titled “Mermaid in the Shell”.

The build started with a frame clutch purse, which, given that it comes with nice hinges and latches, is really a brilliant starting point for a project case. The fact that you can find them shaped like pink seashells really seals the deal for this particular project. A ZitaoTech BB Q10 keyboard — in white, naturally — pairs with a 3.5″ touchscreen as the interface for a Raspberry Pi 3A+. You might be thinking, “great, another toy with an old Pi inside. What can you really do with a Pi3 in 2026?” Well, admittedly, for full-fat desktop Linux, the 3A+ is looking a bit long in the tooth and short in the RAM.

If you are willing to work within its constraints and not run a full Linux desktop, though, 512 MB is plenty of RAM to work with. [cc] has set up a custom terminal user interface (TUI) to give her everything she needs — wifi, bluetooth, a full terminal, a remote serial monitor, a local LLM chatbot, a PDF reader, a text editor, and, of course, a mermaid digital pet. That last one is user-skinnable, though, so if you want a terminal tamagotchi of your own, you can grab the code off GitHub and swap the spites for whatever you want.

Thanks to [cc] for the tip. Whether your next build is dripping the femme-ergy and kawaii as heck, or just utilitarian tacticool, please let us know in the tips line.

Remember, too, that an aesthetic doesn’t need to be skin-deep. We have some tips for good-looking PCBs here that are relevant because they now come in pink — as we saw with this wearable circuit sculpture.

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We notice there are a lot of hacks on YouTube lately, but we don’t share enough hacks about YouTube. That’s why [PortalRunner]’s latest oeuvre is interesting: it’s a video that gives you a different picture depending on the selected bitrate.

Watch it at 1080p, you get one thing; at 360p, the image is completely different. The hack relies on understanding precisely how YouTube cuts down videos — because if you haven’t uploaded a video there before, you might not know the creator doesn’t have to encode all of those options; they’re invited to upload in the highest possible definition, and YouTube reencodes the rest.

1080p and 720p films are shown at 60FPS, while 360p and below are 30FPS– so that’s one way to hide the difference. Since YouTube drops every second frame when encoding the lower-quality video, images you want in the HD version can be kept only in even-numbered frames that YouTube will remove. That seems easy enough, but how does [PortalRunner] avoid the low-quality image flickering in at 30 FPS when watching in higher definition?

Well, that relies on understanding exactly how downsampling works: going from 1080p to 360p means tossing out every third pixel in both the horizontal and vertical directions. If you’re careful, it turns out you can craft an image that vanishes when the 3×3 grid of pixels it’s made of at 1080p is averaged to a single background-colored pixel at 360p. [Portal Runner] is using vertical stripes here, but that’s not the only way to do it. Just to be sure the message came through loud and clear at 1080p, though, the original image, not the stripy one, is used on the odd-numbered, discarded frames.

Hiding the 1080p video is only half the battle: he needs to get those frames not to average specifically to the background color, but to make his new images. That’s a bit tricky, which is why the demonstration uses “1080p” and “lower” as its easter eggs: they fit well inside one another, with the characters lining up one-to-one. That’s without even getting into the hack he’s using with extra i-frames to create thumbnails on the timeline to tell you to ‘subscribe’. Look, it is YouTube, what else can you expect? We’re just glad to see a totally benign hack of the platform that’s holding so many hacks these days.

Of course, real hackers live on the command line, and you can play YouTube there, too.

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For as many speakers as someone can cram into a surround sound system, humans still (generally) only have two ears to listen to those sounds with. This means that, for recording purposes, it’s possible to create incredibly vivid three-dimensional sounds with just two microphones, provided that there’s an actual physical replica of a human ear attached to each microphone. This helps ensure that all the qualities of the sounds are preserved in a way a real human would experience them, and as [David Green] demonstrates, these systems don’t need to be very expensive.

This build doesn’t just use models of human ears for recording sounds through. The silicone ears are mounted on a styrofoam mannequin head as well, which provides some sound isolation between the two microphones, much like a real human head. The ears are mounted in appropriate locations with the microphones installed inside, and the entire microphone apparatus is positioned on a PVC rig with a camera so that binaural audio will be recorded for anything [David] points it at.

Although he had some issues interfacing two microphones using 19th-century technology instead of soldering everything together, the build still eventually came together, and only for around $70 USD. However, this build is a bit dated now, so prices may have changed by now. It’s still a great way to produce realistic stereo sound without breaking the bank, but it’s not the only way of getting this job done.

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While Artemis II was primarily a demonstration flight of the architecture NASA plans to use for future lunar missions, it was also an excellent excuse for the crew to snap some photos of the Moon and Earth with the benefit of modern camera technology. If you’ve been looking forward to seeing more of the crew’s images, you’re in luck, as thousands of new images have recently been released.

Now we don’t mean to beat up on the folks at NASA, but browsing through these images, we couldn’t help but be reminded of an article we saw on PetaPixel that discussed the space agency’s haphazard approach to sharing images online.

It’s really more like an unsorted file dump than anything, made worse by the fact that you have to access it through a government website that looks and performs like it was designed in the early 2000s. There’s even a prominent button that attempts to load a gallery feature that relies on the long-deprecated Adobe Flash. It would be nice to see the situation improved by the time astronauts actually touch down on the lunar surface, but we wouldn’t count on it.

Speaking of old tech, we’ve been following the resurgence of keyboard-equipped smartphones with great interest, as we imagine many of you have been. A recent CNBC article addresses the trend, although it didn’t quite take the nerd contingent into account. We want physical keys so we can work in the terminal and write code without fighting an on-screen keyboard, but of course, that’s not exactly what your average consumer is looking for.

It’s quite the opposite, in fact. A 20-something user referenced in the article explained how the younger generations see the physical keyboard as a way to be less connected to their phones, describing it as “an extra barrier of inconvenience that adds more steps into the thinking process.” If you need us, we’ll be collecting dust in the corner.

As regular readers may know, we’ve also taken an interest in plug-in solar panels recently. So-called “solar balconies” have become quite popular in Europe, but regulatory friction in the United States has prevented them from achieving similar success here. An article in the MIT Technology Review talks about the process of bringing solar balconies to the US, and we’re not overly thrilled with some of the developments it highlights.

As the key hurdle appears to be safety, UL Solutions recommends that balcony solar panels be plugged into a specialized outlet. If putting a regular AC plug on the end of a solar panel can lead to potentially dangerous situations, they believe the solution is to require a different plug that no one could mistake for anything else, with built-in safety features to reduce the risk of electric shock.

That might not seem unreasonable at first, but it actually represents a pretty serious hurdle for many users. Consider that the whole advantage of these panels is the convenience: you can simply open the box, plug them in, and start collecting energy. But if you need to install a special outlet, potentially requiring an electrician, the whole concept falls apart. Expect to hear more from us on this particular subject as it develops.

Finally, Spirit Airline customers weren’t the only ones running into issues this week — a Southwest flight in California was delayed due to complications with a robotic passenger. The bot actually had a ticket, but the flight crew said it still violated the airline’s rules for large carry-on luggage and had to be moved to a different seat. Then somebody realized the robot’s relatively large lithium-ion battery was also in violation of carry-on limits, and it had to be removed and confiscated by authorities. Important details to keep in mind if you happen to be a robot planning your summer vacation.

See something interesting that you think would be a good fit for our weekly Links column? Drop us a line, we’d love to hear about it.

hackaday.com/2026/05/10/hackad…

The idea of using cardboard for a sloppy PC case isn’t new; it’s a time-honored tradition dating back to at least the 1990s. That said, with today’s CNC cutters and other advanced tooling available to hobbyists, you might be curious to see how far you can push the concept. As demonstrated in a recent video by [mryeester], the answer appears to be that good planning and a solid understanding of cardboard’s limitations are as essential as ever.

After having the PC case drawn up in CAD and cut on a professional CNC cutter by a buddy who makes commercial cardboard displays, the installation procedure for the PC components showed where a bit of foresight could have saved a lot of time and effort.

The first problem was that the GPU couldn’t be installed due to wrong measurements on where the IO bracket normally is screwed into the case. Some cardboard cutting later, the GPU slid into place, but of course, there’s no way to screw it down, putting the full weight on the PCIe slot of the mainboard. Fortunately, the mainboard was quite literally bolted into place, and the case consists of multiple layers of corrugated cardboard to add some rigidity.

Next was more carving as the PSU cut-out was designed for an SFX PSU, not an ATX one. After that ordeal, one could say that perhaps a nice thing about a cardboard case is that you get to pick where buttons are located, though this comes with its own logistical issues.

Finally, mounting side panels turned into another chore, with perhaps some engineering possible to make it work better. For example, we recently looked at making cardboard hinges that would look pretty good on a cardboard PC case. You can also waterproof cardboard and make it much stronger, turning a throwaway, temporary cardboard solution into something that will last for years, even with occasional exposure to moisture and a water-cooling leak.

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For the last few years, the must-have feature that companies are competing to show off on their filament deposition 3D printers is multi-material printing. Be it tool swapping or a material-changing system, everyone wants to show they can give you the capability to make multicoloured plastic tchotchkes. So far, that hasn’t really been the case in the world of at-home resin printing — until now. A company called Polysynth, headed by a fellow named [Eric], hopes you’ll pay a premium for the ability to make multimaterial resin prints, and they show some interesting use cases in the video below.

The technique is simple: instead of one resin tank underneath the dipping build plate, [Eric]’s Polysynth printer has a carousel of up to eight small circular tanks. To avoid cross-contamination from uncured resin, the print needs to be cleansed between alternating dips in the different resin vats. Rather than add a wash vat and slow the process down that way, [Eric] and his team decided to use centrifugal force: they just spin the print really, really fast to fling all the uncured resin to the sides of the vat. Yes, really.

The hard part isn’t the resin-removing spin cycle — the hard part is stopping the spin at the precise orientation the part started at, to within a few microns. For that, he’s using a sort of kinematic linkage to lock the spinning portion back into place using a servo. It seems to work, based on the demonstration in the video embedded below. Even better, [Eric] shows off a resin conductive enough to use for fully printed, multilayer PCBs. We doubt SLS will ever compete with traditional fabs on volume, but for fast turnaround without waiting on parts from China, the conductive resins could open up some killer apps for this kind of printer. That and dental: printing gums and teeth of dentures in one solid go is likely to appeal to users in that space.

What do you think? Tipster [Aaron Tagliaboschi] was interested enough to send in the video, and we’re grateful that he did. It’s early days yet, and you cannot buy one of these machines just yet. Since it’s a commercial product, you’ll be starting from scratch if you want to build your own.

It wasn’t that long ago that the only way to get a home resin printer was to build it yourself, and it’s still an option that might save some coin. If you go that route, why not try spinning? We hear that’s a good trick, so let us know if you try it.

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Car airbags are both a very simple concept and a marvel of engineering, replacing the bone-shattering impact of unforgiving plastic and steel with a relatively soft landing in a funky-smelling air cushion. This deceptively simple concept requires that the gas generator activates only when there is a crash and finishes filling the airbag in the milliseconds before the squishy human’s cranium with its soft filling attempts to occupy the same space as said airbag. This makes mad Aussie bloke [Turnah81]’s attempt at DIY-ing a car airbag a most daring proposition.

Rather than messing about with an IMU and microprocessors, he went low-tech with an inertial fuel cut-off switch. These are mechanical switches that hold a steel ball in place with a magnet until a sufficiently large force — like a crash — dislodges the ball and triggers an event. Usually, a switch like this cuts off the fuel pump.

After a bit of fun with a crash-test rig and the airbag of a salvaged steering wheel, a DIY airbag was assembled using a compressed-gas cylinder instead of the fancy gas generator, along with an electrically triggered valve. Here, you can already see why modern airbags use a gas generator, as it is simply far more compact.

For the bag itself, a pillow case was adapted, with the subsequent crash test — as pictured above — going about as well as you can imagine. After this, he tried a few improvements, like using a bin liner and detonating some fuel, but it seems that the gas generator is very hard to beat for producing a large amount of gas in very little time.

Meanwhile, the inertial cut-off switch turned out to be more than sufficient for this purpose, and it was also used to trigger the original airbag. Of course, with how cheap those off-the-shelf airbag units are and are tested to be fit for purpose, you’d never DIY them for actual use in a car unless you were stark raving mad.

Airbags have a checkered history. There are some places you shouldn’t try to save costs.

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This project is perhaps the single most passive-aggressive thing we’ve ever seen on this site: rather than tell someone directly to ‘shut up’, [Blytical]’s speech jammer lets you hack their brain from across the room to stop them from speaking. It’s also a bit of an object lesson in why you shouldn’t just copy reference implementations without careful study — by his own implementation, [Blytical] was forced to learn a lot more than he intended going into this project.

The brain hack behind it is called ‘delayed auditory feedback’: by feeding their speech back to the target with a short delay — only 50 to 200 ms — it creates a confounding effect that is apparently very difficult to speak through. The array of ultrasound transducers is used to accurately aim the audio by serving as an inaudible, low-spread carrier wave, as we saw in another project this year. A shotgun mike picks up the audio from the speaker you wish to harass, and an array of audio processing circuitry takes care of the rest.

That’s where problems happen, as [Blytical] admits he just tossed some reference implementations onto a PCB without bothering to think too hard about what he was doing. It’s the datasheet version of vibe coding, and it usually goes about as well — sometimes perfectly, but rarely without a lot of troubleshooting. That troubleshooting is really, really hard when you don’t quite understand why things were laid out the way they were on the datasheet. We don’t blame [Blytical], you can learn a lot when you bite off more than you can chew. The fact that he risked this failure mode rather than do the whole thing in software with a Pi says good things about how he’s conducting his education.

It’s a shame, though, because we’ve been waiting to see another one of these speech jammers in action for quite some time. Perhaps someone will try again; the ultrasonic array portion seems solved, so if the delay circuit was the problem, perhaps a tiny tape loop would suffice.

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hackaday.com/2026/05/10/speech…

The way that the sense of smell works is that olfactory sensory neurons (OSNs) are wired up to olfactory receptors (ORs) in the nasal epithelium, from which they send signals to the brain. Once arrived there, a hierarchy of processing results in us experiencing the sensation of ‘smelling’. Exactly how the olfactory receptor-to-brain mapping works during development, and whether its physical pattern in the nasal epithelium is replicated in the brain, remained major questions until now. In a study published in Cell by [David H. Brann] and others, many of these questions have now been answered, at least for mice.

As it turns out, the mapping between OSNs and ORs isn’t performed by a random selection process, but instead creates a receptor map that’s closely matched between the nasal epithelium and the brain. What has complicated answering this question up till now is that the nasal epithelium isn’t a flat surface, but a convoluted labyrinth that maximizes surface area to smell better.

The second issue was linking the physical location of OSNs and gene expression in the nasal epithelium. Using a new approach, the researchers showed an intricate patterning in this epithelium, with the basal stem cells from which it regenerates maintaining this patterning. This makes for a system very similar to, for example, the auditory system, where the detection of frequencies in the inner ear, as a linear system, is found to be replicated in the brain.

Although it does not provide us with all the answers yet about how this genetic patterning works, it offers a glimpse at a fascinating system that would seem to be used repeatedly across sensory systems. It may also provide potential treatments for medical conditions affecting the olfactory system, whereby the sense of smell is missing, reduced, or oddly miswired, for example, after a SARS-CoV-2 infection of the olfactory nerve that leads to symptoms such as a constant sensation of a burning smell.

You have to wonder if a better understanding of the nose will revive interest in digitally creating and sending smells?

hackaday.com/2026/05/10/tracin…

The bicycle is an invention that has not changed in its fundamentals since the first recognisably modern machines appeared in the closing years of the 19th century. Its frame uses a structure of two triangles, its wheels are equal in size, and it’s propelled by a pedal crank and (in most cases) a chain. Bicycles have improved vastly in materials and performance, but if you were to wheel a 2026 tourer into an 1886 bike shop, the Victorian proprietor would recognise it. Only a very brave engineer would try to fundamentally change such a formula, but here’s [Not programming] with a crankless bicycle.

The idea is to replace the crank’s circular motion with a linear one, thus providing a more constant propulsion. The build was inspired by another that used a sinusoidal track in a rotating cylinder to achieve the necessary conversion. This design takes a different tack, using an arrangement of gears and freewheels he describes as a mechanical rectifier to convert the back-and-forth motion of pedaling into rotation. The pedals themselves are stirrups mounted at each end of a V-belt.

This build is an exercise in pushing the limits of 3D print strength, as prototype after prototype shears under load. He does finally get the thing to work, though, and we admire his persistence. Oddly, this isn’t the first 3D-printed bicycle geartrain we’ve seen.

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CDMA2000 was one of the protocols defined for 3G networks and is now years out of date and being phased out worldwide. Nevertheless, there are still vast numbers of phones that will happily connect to it, creating an opportunity for hackers seeking to run their own cellular networks. [Chrismoos] recently made this endeavour significantly easier by releasing 1xBTS, a Rust implementation of the lower three layers of a CDMA2000 network.

The lowest layer of the stack is an SDR for the actual radio communications. It’s been tested with the USRP B200 and B210, the LimeSDR Mini 2, and the BladeRF Micro 2.0. The code might work with certain other SDRs using the SoapySDR abstraction layer. The SDR is controlled by the base station (BTS) software, which, in turn, is controlled by the base station controller (BSC) over an Abis link. The BSC manages channels and mobile device associations, and exchanges frames with the mobile switching center (MSC), which handles message switching.

The stack includes standard 3G verification; before a handset can authenticate to the network, its details must be added to the home location register (HLR). Once authenticated, the handset can access all standard services: inbound and outbound voice calls via a SIP gateway, inbound and outbound SMS, and data packet transfers. A web dashboard provides a convenient management platform that includes packet tracing.

It should be noted that using this carelessly is legally hazardous; radio transmissions are strictly regulated in most countries, particularly in the cellular bands. If you’d still like to run your own cell network, we’ve also seen a few other efforts, such as this 4G implementation, this 1G recreation, and a GSM network made for a hacker camp.

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After Noctua recently released CAD files for a range of their computer fans, one of the first thoughts that popped up for most people was: Can you just to 3D print their fans? Even though Noctua begs you not to 3D print the files and even says they changed the design slightly so it wouldn’t be the same anyway, the question persists. Fortunately, [Steve] of Gamers Nexus is here to help us answer the question of whether it makes sense to 3D print a computer fan.

Unsurprisingly, the answer is mostly a resounding ‘no’. After reworking the original CAD models to be both printable on a Bambu Lab FDM printer and printing the parts in PLA, the arguably most important part, the motor, still had to be sourced from an original Noctua fan. Although you could source a cheaper motor, that could change the fan’s characteristics.

The other issue is materials. The special polymer that Noctua uses for its fans is designed not to change shape significantly when the fan blades are spinning, whereas PLA and basically every other thermoplastic will likely deform enough to hit the inside of the fan with the blades. For this reason, a 3 mm gap was used in the PLA print compared with the approximately 0.5 mm gap of the original Noctua fan.

Using the professional fan tester and semi-anechoic chamber over at Gamers Nexus, the original and replica fans were compared, showing that the 3D-printed fan had a similar noise profile but produced only about half the airflow. This is likely due to the blade shape and angle, the increased gap, and probably a dozen other details that presumably justify putting a cool $40 down for the original fan.

In short, you’re probably best off using these Noctua fan CAD models for fit testing in a larger CAD model, or 3D printing it for a similar purpose, rather than for a functional fan design. At least now we know. Thanks, [Steve].

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There comes a point in everybody’s life when things that they were a part of are presented as history, and for the 8-bit generation, that time is now. It’s interesting to see the early history of 8-bit home computers presented as history, not from a 2026 perspective but from the early 1990s. The BBC archive has recently posted a retrospective from 1992 looking at ten years of the Computer Literacy Project, a British government programme intended to equip the young people of the 1980s with the skills they would need to approach the information age. It’s a much more immediate history of something which was largely still in place at the time, making it a time capsule in which this past isn’t quite the other country we see it as today.

The Computer Literacy Project was run by the nation’s broadcaster and included a raft of TV programming about computers, as well as the commissioning of a machine specifically for the project. You know this machine as the Acorn BBC Micro, and aside from eventually providing the genesis of what would become ARM, it remains one of the most high-spec 8-bit machines in terms of built-in hardware. We hear from the luminaries of Acorn about the development of this machine, and then the film moves into some of the wider cultural effects.

If you were there, you’ll doubtless remember some of the TV programmes featured, and you might have used a BBC Micro at school. If you weren’t there, it’s an encapsulation of the promise on offer in that era, an optimism that seems sad when you reflect that educational computing descended into learning Microsoft Word during the following decade. It would be another two decades before the Raspberry Pi and BBC micro:bit picked up that fallen torch.

The Beeb, it seems, has long had an interest in home computers. Schools, too.

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Recently [Camden Bowen] took a swing at machining a two-stroke engine out of billet aluminium, following adventures in 3D printing such an engine, as well as building one out of parts largely sourced from a hardware store. The sketchiest part here is probably the use of only a basic mill and lathe, making the milling of certain shapes a definite OSHA violation.

Two-stroke internal combustion engines are pretty simple from a mechanical point of view, with designs readily available. Add in a suitable material to machine and a modicum of machining and welding skills, and presto, you got yourself a not too shabby looking engine.

Of course, back in reality things are a bit more hairy. Not only are there many different ways to produce the parts – with some coming with a time penalty, monetary penalty, or both – but there are also myriad ways to hurt yourself and/or others. Fortunately [Camden] scraped by with just some (expensive) lessons learned and a major ruined part.

The final design features a single cylinder, with an initial pressure test showing a solid 150 PSI (10 bar) of compression. With that encouraging sign, a coil pack and contactor were added for some spark and a test run with the usual premixed gasoline-oil fuel.

Boringly, the engine mostly just runs and work as it should. This is of course not unexpected, much like how following the recipe for a pie produces said pie. But it does demonstrate how easy things are when you do not stray off the beaten path. The only significant issue was the flywheel wobbling slightly, likely due to a small manufacturing glitch, but this should not cause too many issues.

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We got asked a great question in the mailbag segment on the Podcast this week: are there hacks that we have read about on Hackaday that we use in our everyday life? The answer was absolutely yes, and I loved Tom’s take it often goes the other way – he sees a hack, tests it out, and then writes it up.

But I started looking around the office and I found more examples of projects that were absolutely inspired by projects I had seen on Hackaday, yet weren’t the same. I made a DIY mechanical keyboard because I saw someone else do it. There are a few home-made battery packs that I probably wouldn’t have attempted without having read about someone doing the same thing. I riffed on [Ted Yapo]’s Tritiled project, making a slightly inferior, but workable knockoff, and they’ve been glowing for many years now.

That got me to thinking about reproducing a project versus taking inspiration from it, and though I enjoy both, I’m find myself most often in the “inspiration” mode. I just can’t leave well enough alone, even when I’m fundamentally copying someone. NIH syndrome? Expediency? Probably both, and sometimes with a dose of hubris or feature creep.

Looking back at [Ted]’s TritiLED, though, I found some great examples in both the rebuild and redesign modes on Hackaday.io. [schlion]’s Making Ted Yapo’s TritiLED couldn’t be a clearer example of the former, and it’s great to look over his shoulder and appreciate all the lessons he learned along the way. [Stephan Walter]’s Yet another ultra low power LED is inspired by [Christoph Tack]’s Ultra low power LED, which is in turn inspired by [Ted]’s project, like a conceptual grandchild.

In a way, I look at this like with music: sometimes you play the notes the way they were written down, and sometimes you riff on someone else’s theme. Both are equally valid, and both owe a debt to the upstream source. Is Hackaday the hackers’ jazz club? And which of these modes do you find yourself working in most?

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