Connecting a headless Raspberry Pi to a wireless network can be quite a paradoxical situation. To connect it to the network, you need to open an SSH connection to configure the wireless port. But to do so, you need a network connection in the first place. Of course, you can still get command-line access using a USB-to-UART adapter or the Pi’s ethernet port – if present – but [Arsenijs] worked out a much more convenient solution for his Hackaday Prize entry: The pyLCI Linux Control Interface.
His solution is a software framework written in Python that uses a character display and buttons to make a simple hardware interface. This allows you to configure all important aspects of a Raspberry Pi – or any other Linux SBC – from a tidily organized click-and-scroll menu. [Arsenijs] implemented a whole bunch of useful tools: There’s a network tool to scan and connect to WiFi networks. A systemctl tool that lets you manage the services running on the system, which is especially helpful when you need to restart a stuck service. A partition tool helps with viewing and unmounting mass storage devices. He’s even planning to add a filesystem browser.
With his Open Source project, [Arsenjs] aims to shorten the development time for embedded projects by taking out the efforts of implementing the basic interface functions from scratch. Indeed, there are countless scenarios, where a basic display interface can be of great value. Given the great project documentation and the fact that this can work with virtually any Arduino or Raspberry Pi LCD-pushbutton-hat or shield, we’re sure this is going to be used a lot. Enjoy the video!
Continue reading “Hackaday Prize Entry: An Interface For The Headless Linux System”
It is easy to imagine how early man started using rocks and then eventually developed better and better tools until they created the hammer. Some simple tools took a little longer to invent. The spirit level, for example, didn’t exist until sometime in the last half of the 1600’s.
The idea is simple. A clear tube holds a liquid and a bubble. When the bubble is in the center of the tube, the device is level in the direction of the tube. [Mark Williams] has a slightly more involved approach. He took an internal measurement unit (IMU) and a Raspberry Pi to create a modern take on the spirit level.
Continue reading “Raspberry Pi Levels with You”
A lot of old science fiction movies show people wearing the same–or nearly the same–clothes. We’re left guessing if this is because there is a single centralized plant mass-producing skin-tight jumpsuits, or if everyone is under orders to dress the same. Now that we live in the past’s future, it looks like science fiction was a poor predictor of fashion. People want variety.
Which calls to mind development boards. How many different ones do we need? Need doesn’t matter, because we have plenty of them. There may be strong leaders: in the 8-bit world, you think of the Arduino, and on the Linux side, maybe the Raspberry Pi. But there are options.
[Eric Brown] recently compared several inexpensive development boards from FriendlyARM including the NanoPi M3, the NanoPi M1, and the NanoPC-T3. These range from about $11 to $60 with the M3 costing $35. You can see an M1 booting on an HDMI screen in the video below.
Continue reading “FriendlyARM: A Different Flavor of Raspberry”
Raspberry Pi clusters are a dime a dozen these days. Well, maybe more like £250 for a five-Pi cluster. Anyway, this project is a bit different. It’s exquisitely documented.
[Nick Smith] built a 5-node Pi 3 cluster from scratch, laser-cutting his own acrylic case and tearing down a small network switch to include in the design. It is, he happily admits, a solution looking for a problem. [Smith] did an excellent job of documenting how he designed the case in CAD, prototyped it in wood, and how he put the final cluster together with eye-catching clear acrylic.
Of interest is that he even built his own clips to hold the sides of the case together and offers all of the files for anyone who wants to build their own. Head over to his page for the complete bill of materials (we didn’t know Pis were something you could order in 5-packs). And please, next time you work on a project follow [Nick’s] example of how to document it well, and how to show what did (and didn’t) work.
If 5 nodes just doesn’t do it for you, we suggest this 120-node screen-equipped monster, and another clear-acrylic masterpiece housing 40 Pis. This stuff really isn’t only for fun and games. Although it wasn’t Pi-based, here’s a talk at Hackaday Belgrade about an ARM-based SBC cluster built to crunch numbers for university researchers.
The subreddit for Shower Thoughts offers wisdom ranging from the profound to the mundane. For example: “Every time you cut a corner you make two more.” Apparently, [Harin] has a bit of an addiction to the subreddit. He’s been sniffing the CAN bus on his 2012 Hyundai Genesis and decided to display the top Shower Thought on his radio screen.
To manage the feat he used both a Raspberry Pi and an Arduino. Both devices had a MCP2515 to interface with two different CAN busses (one for the LCD display and the other for control messages which carries a lot of traffic.
The code is available on GitHub. There’s still work to do to make the message scroll, for example. [Harin] has other posts about sniffing the bus, like this one.
We’ve covered CAN bus quite a bit, including some non-automotive uses. We’ve even seen the CAN bus for model railroading.
[Mr. Name Required] pointed us to a great video on the modeling of a replica Apple /// to the small scale needed to contain a Raspberry Pi by [Charles Mangin].
[Mr. Name] pointed out that the video was a great example of the use of reference photos for modeling. [Charles] starts by finding the references he needs for the model. Google image search and some Apple history websites supplied him with the required images.
He modeled the Apple /// in Autodesk 123. It has sketch tools, but he chose to craft the paths in iDraw and import them into the software. This is most likely due to the better support for boolean combination tools in vector editing software. Otherwise he’d have to spend hours messing with the trim tool.
Later in the video he shows how to change the perspective in photographs to get a more orthographic view of an object. Then it’s time for some heavy modeling. He really pushes 123 to its limit.
The model is sent off for professional 3D printing to capture all the detail. Then it’s some finishing work and his miniature Apple /// is done. Video after the break.
Continue reading “Build a Replica Apple ///”
[Oitzu] in Germany wrote in to let us know about a series of short but very informative blog posts in which he describes building a series of solar-powered, networked birdhouses with the purpose of spying on the life that goes on within them. He made just one at first, then expanded to a small network of them. They work wonderfully, and [Oitzu]’s documentation will be a big help to anyone looking to implement any of the same elements – which include a Raspberry Pi in one unit as a main gateway, multiple remote units in other birdhouses taking pictures and sending those to the Pi over an nRF24L01+ based radio network, and having the Pi manage uploading those images using access to the mobile network. All with solar power.
Continue reading “Networked Solar Birdhouses Deep in the Woods”