The Raspberry Pi Zero is small enough that it could almost be mistaken for a USB gadget, rather than a standalone computer. Maybe that was the inspiration that drove [Novaspirit] to completely “donglify” his Zero.
This is a great convenience hack if you’ve got a Zero just kicking around. With minimal soldering, he converted the Zero’s onboard female USB jacks into a male USB plug. From there on out, it’s all software, and the video (embedded below) takes you through all the steps on Windows.
A lot of people assume that the product development cycle involves R&D, outsourcing to a Chinese manufacturer, and then selling the finished product. It’s almost ingrained in our heads that once a prototype has been developed, the next step involves a visa and airplane tickets. Here is a guide that will explore a few other options, and why outsourcing may not be appropriate for everyone.
First, let’s talk about goals. We’ll assume you’re not a large company, and that you don’t have a huge budget, and that you’re just getting started with your product and don’t have big volumes; a startup trying to sell a kit or breakout board, or a consumer electronics product. Your goals are the following:
Validate your product in the market. Build a minimum viable product and get it in the hands of lots of users
Get the most bang for your limited bucks. All money should go towards getting products out the door
Reduce risk to your company so that any single failure doesn’t crater the whole operation and you can safely grow.
Mount an umbrella to a drone and there you go, you have a flying umbrella. When [Alan Kwan] tried to do just that he found it wasn’t quite so simple. The result, once he’d worked it out though, is haunting. You get an uneasy feeling like you’re underwater watching jellyfish floating around you.
A grad student in MIT’s ACT (Art, Culture and Technology) program, [Alan’s] idea was to produce a synesthesia-like result in the viewer by having an inanimate object, an umbrella, appear as an animate object, a floating jellyfish. He first tried simply attaching the umbrella to an off-the-shelf drone. Since electronics occupy the center of the drone, the umbrella had to be mounted off-center. But he discovered that drones want most of their mass in the center and so that didn’t work. With the help of a classmate and input from peers and faculty he made a new drone with carbon fiber and metal parts that allowed him to mount the umbrella in the center. To further help with stability, the batteries were attached to the very bottom of the umbrella’s pole.
In addition to just making them fly, [Alan] also wanted the umbrella to gently undulate like a jellyfish, slowly opening and closing a little. He tried mounting servo motors inside the umbrella for the task. These turned out to be too heavy, but also unnecessary. Once flying outside at just the right propeller speed, the umbrellas undulated on their own. Watch them doing this in the video below accompanied by haunting music that makes you feel you’re watching a scene from Blade Runner.
We were initially skeptical of this article by [Aleksey Statsenko] as it read a bit conspiratorially. However, he proved the rule by citing his sources and we could easily check for ourselves and reach our own conclusions. There were fatal crashes in Toyota cars due to a sudden unexpected acceleration. The court thought that the code might be to blame, two engineers spent a long time looking at the code, and it did not meet common industry standards. Past that there’s not a definite public conclusion.
[Aleksey] has a tendency to imply that normal legal proceedings and recalls for design defects are a sign of a sinister and collaborative darker undercurrent in the world. However, this article does shine a light on an actual dark undercurrent. More and more things rely on software than ever before. Now, especially for safety critical code, there are some standards. NASA has one and in the pertinent case of cars, there is the Motor Industry Software Reliability Association C Standard (MISRA C). Are these standards any good? Are they realistic? If they are, can they even be met?
When two engineers sat down, rather dramatically in a secret hotel room, they looked through Toyota’s code and found that it didn’t even come close to meeting these standards. Toyota insisted that it met their internal standards, and further that the incidents were to be blamed on user error, not the car.
So the questions remain. If they didn’t meet the standard why didn’t Toyota get VW’d out of the market? Adherence to the MIRSA C standard entirely voluntary, but should common rules to ensure code quality be made mandatory? Is it a sign that people still don’t take software seriously? What does the future look like? Either way, browsing through [Aleksey]’s article and sources puts a fresh and very real perspective on the problem. When it’s NASA’s bajillion dollar firework exploding a satellite it’s one thing, when it’s a car any of us can own it becomes very real.
The Nintendo Power Glove was one of the amazing 1980s experiments in alternative user interfaces for video games. It was bad. It was cool, but it was bad. Recently, interest in the Power Glove has grown thanks to an amazing stop motion animator. Prices of these gloves have gone through the roof, and the Power Glove is in the middle of a resurgence not seen since the feature-length motion picture advertisement for Super Mario Bros. 3.
[Nolan Moore] is a fan of the Power Glove, and after finding a highly collectible new in box Power Glove, he decided to take this wearable to the next level. It’s now sporting custom circuit boards, it can control a drone, and talks wirelessly to every device on the planet. It’s also [Nolan]’s entry for the Hackaday Prize.
First up, the glove itself. [Nolan] was lucky enough to find a new, in shrink-wrapped plastic, Famicom Power Glove. His old one had been in storage for 27 years, and this new old-stock version gives him a beautiful matte glove, flex sensors that work, and brand new everything. You can take a look at the unboxing here.
A Power Glove is only as cool as the electronics inside, and that means tearing out the old boards, the old ultrasonic sensors, and a rats nest of wiring. This meant [Nolan] had to spin a few PCBs, integrating a Teensy, an IMU module, battery, and an ESP8266. This is the Power Glove as it would be invented today – perfection in 80s cyberpunk.
We first saw [Nolan]’s Power Glove at the Bay Area Maker Faire last summer. Here, [Nolan] was flying a quad around a netted cage, his replacement Power Glove electronics, and his fist-pumping grin. It’s a great project, and one we’re happy to show off in the Hackaday Prize.
No one watches video anymore. Cable cutters are digging into Verizon’s profits, and YouTube is a shadow of its 2005 self. What are people consuming now? Animated gifs. This is the bread and butter of the meme economy. Personally, all my investments are sunk deep into Gandolf / Balrog gifs, with each character replaced with Trump and Hillary. I expect a tidy profit on November 9th.
With animated gifs being the de facto method of sharing moving pictures, the world will belong to those who can create them. Phones are fine, but strangely video cameras, DSLRs, and other high-end photography equipment are the norm. This is idiotic, of course, because high-definition images are just a fad, and audio is useless.
For the hardware, [Nick] went with a Raspberry Pi and Raspberry Pi camera. A combination of software ranging from PiCamera, GraphicsMagick, and GifCam turns this tiny bit of hardware into a machine dedicated to content creation in the hippest new medium. Other hardware includes a battery – either a normal LiPo ‘pouch’ cell, or an 18650 cell. Other hardware includes an Adafruit Powerboost 500 charge controller and a neat illuminated push button.
The 3D-printed enclosure is where this project really shines. Hearkening back to an older time, this camera includes a real viewfinder for all your gonzo giffing. The camera is charged through a completely normal USB port, and even the Pi’s SD card is accessible without disassembling the camera. There are even some paper wrappers for this camera to give it a 90s disposable camera aesthetic.
Of course, this isn’t the first camera dedicated to the creation of animated gifs. Before the C.H.I.P., Next Thing Co released OTTO, a camera designed for gifs. [Nick]’s project, though, is a camera dedicated completely to gifs. It is the greatest technical achievement of our time, for the creation of content in the greatest artistic medium.
It’s the Hack ‘O Lantern edition! First up, Slic3r is about to get awesome. Second, Halloween is just around the corner, and that means a few Hackaday-branded pumpkins are already carved. Here’s a few of them, from [Mike] and [yeltrow]:
The latest edition of PoC||GTFO has been released. Holds Stones From The Ivory Tower, But Only As Ballast (PDF and steganography warning). This edition has a reverse engineering of Atari’s Star Raiders, [Micah Elisabeth Scott]’s recent efforts on USB glitching and Wacom tablets, info on the LoRa PHY, and other good stuff. Thanks go to Pastor Manul Laphroaig.
Pobody’s Nerfect in Australia so here’s a 3D printed didgeridoo. What’s a didgeridoo? It’s an ancient instrument only slightly less annoying than bagpipes. It’s just a tube, really, and easily manufactured on any 3D printer. The real trick is the technique that requires circular breathing. That’s a little harder to master than throwing some Gcode at a printer.
[Chris Downing] is the master of mashed up, condensed, and handheld game consoles. His latest is another N64 portable, and it’s a masterpiece. It incorporates full multiplayer capability, uses an HDMI connector for charging and to connect the external breakout box/battery, and has RCA output for full-size TV gameplay. Of note is the breakout board for the custom N64 chip that puts pads for the memory card and a controller on a tiny board.