[TVMiller]’s description of his project is epic enough to deserve a literal copy-paste (something our readers often praise us about). In his own words, “Having discovered several spare Midichlorians in my liquor cabinet, I trained and applied them to opening a large cumbersome gate. The FORCE motion travels through my inner what-nots and is translated by the Pebble Classic accelerometer toggling a command sent to the (Particle) Cloud (City) which returns to the Particle Photon triggering a TIP120 to fire a button on an existing RF transceiver. May the ridiculous hand gestures be with you, always.” Thus was born the Gate Jedi , and you’ll need exactly 47 Midichlorians, and some other trivial parts, to build one.
The Pebble watch hooks up to his android smart phone. An android app sends the accelerometer data to the Particle (previously called Spark) cloud service. From there, the data is pushed to the Photon IoT board which runs a few lines of code. Output from the Photon turns on a TIP120 power transistor, which in turn triggers the existing RF trans receiver that opens the Gate.
This looks way cooler than the Light Sabre hacks. Check out the video of him summoning the Force. And if you’d like to do more, try integrating gesture controls with this Pebble Watch hack that turns it into a home automation controller.
Continue reading “Open Sesame, from a Galaxy far, far away.”
The Printrbot Simple Metal is a good 3D printer, with a few qualifications. More accurately, the Printrbot Simple Metal is a good first 3D printer. It’s robust, takes a beating, can produce high-quality prints, and is a great introduction to 3D printing for just $600. There are limitations to the Printbot Simple Metal, the most important is the relatively small 150mm cubed build volume.
[ken.do] wanted to print large parts, specifically scale aircraft wings and panels. While the Printrbot can’t handle these things normally, the design of the printer does lend itself to increasing the size of the build volume to 500mm long and 500mm high.
Increasing the build height on the Printrbot is as simple as adding two longer smooth rods and a single threaded rod to the Z axis. Increasing the X axis is a bit trickier: it requires a very flat sheet that doesn’t warp or bend over 500 mm, even when it’s being supported in different places. [ken.do] is engineering stiffness into a build plate here. The solution to a huge bed is a two kilogram aluminum bed supported by heavier rails and riding on a massive printed bushing block. Does it work? Sure does.
If you want to print tall objects, the current crop of 3D printers has you covered: just get a delta, and you’re limited only by the length of the extrusion used in the body. Creating big objects in all three dimensions is a marginally solved problem – just get a big printer. Big printers have drawbacks, notably the incredible power requirements for a huge heated build plate.
The ability to print long objects is a problem that’s usually not addressed with either commercial 3D printers or RepRaps. We’re glad to see someone has finally realized the limitations of the current crop of 3D printers and has come up with a way to turn a very good first printer into something that solves a problem not covered by other 3D printers.
Researchers at University College London successfully transferred data over an optical transmission system at a rate of 1.125 Tb/s. That’s over ten times as fast as typical commercial optical systems, and thousands of times faster than the standard broadband connection. The study appeared in Scientific Reports and takes advantage of encoding techniques usually seen in wireless systems.
The prototype system uses fifteen channels on different wavelengths. Each channel used 256QAM encoding (the same as you see on cable modems, among other things). A single receiver recovers all of the channels together. The technology isn’t commercially available yet. It is worth noting that the experiment used a transmitter and receiver very close to each other. Future tests will examine how the system performs when there are hundreds or thousands of feet of optical fiber between them.
Continue reading “Suddenly, 4G Feels Slow”
Just in time for Valentine’s Day, here’s a project out of the LVL1 hackerspace in Louisville that should warm the heart of that special someone in your life. Behold the Magic 8 of Hearts.
The metaphors are somewhat mixed here, what with the heart-shaped box, the mysterious black window of a Magic 8-ball, and the cheesy once-a-year sayings like those printed on Sweethearts candies. [JAC_101] began surgery by punching a hole in the plastic heart for an OLED display. The white on black display evokes the Magic 8-Ball look, although adding a blue filter would have nailed it. A 3-axis accelerometer detects shaking motion and an Arduino Nano selects a message to display. Some white LEDs light up the enclosure and add a little pizzazz. As a bonus, the whole thing is inductively charged – no extra holes needed in this heart.
If your true love would appreciate something a little flashier, try this animated LED Valentine heart. And if you’re successful in your romantic endeavors, you might just find yourself building these ultra-geeky wedding invitations.
Continue reading “Magic 8 of Hearts Plies Your True Love with Cheesy Sayings”
It’s a wonder that drivers are given so little insight into what’s going on under the hood. We mostly have the illusion of insight in the form of gauge, idiot lights, and when things get real, our eyesight and sense of smell. The older a car gets, the more important it is to be aware of the condition of its systems.
[Mjtrinihobby] drives a beat-up 1999 Honda Civic. He likes creating automation systems as a hobby and figured that his car would make an excellent test subject. [Mjtrinihobby] began this project with several features in mind. He wanted more control over several of the car’s systems—the A/C, lights, the fuel level, and the blower motor in the cabin to name a few—and a compact, user-friendly way to interface with them that could handle road shock and the heat of the climate he calls home.
He chose a Windows 8.1 netbook with a touchscreen display for the user interface. The netbook is running FlowStone, which is a robust graphical programming language with a long list of applications. A LabJack data acquisition board (DAQ) handles the communication between the car’s systems and the netbook.
This is much more than just a cool way to control the climate and make the headlights come on when darkness falls. For instance, [Mjtrinihobby]’s system continuously monitors the alternator’s voltage. If it measures between 7 and 12V, a friendly voice warns about possible alternator failure and disables high-draw accessories so the car has a fighting chance of making it to the mechanic.
Be sure to check out the demonstration video after the break. If OBD-II car hacks are more your speed, try building an RGB tachometer.
Continue reading “Talking Car Automation Computer is like KITT without the Sass”
[BrittLiv] and her boyfriend got in one too many fights about who set the alarm. It’s the only argument they seem to repeat. So, true to her nature as an engineer, she over-engineered. The result was this great puzzle alarm clock.
The time displayed on the front is not the current time. Since the argument was about alarm times in the first place, [BrittLiv] decided the most prominent number should be the next alarm. To hear the time a button (one of the dots in the colon) must be pressed on the front of the clock. To set the alarm, however, one must manually move the magnetized segments to the time you’d like to get up. Processing wise, for a clock, it’s carrying some heat. It runs on an Intel Edison, which it uses to synthesize a voice for the time, news, weather, and, presumably, tweets. It sounds great, check it out after the break.
All in all the clock looks great, and works well too. We hope it brought peace to [BrittLiv]’s household.
Continue reading “Puzzle Alarm Clock Gets Couple Up In The Morning”
Take three NRF24L0+ radios, two Arduino Nanos, and a Raspberry Pi. Add a bored student and a dorm room at Rice University. What you get is the RRAD: Rice Ridiculously Automated Dorm. [Jordan Poles] built a modular system inspired by BRAD (the Berkeley Ridiculously Automated Dorm).
RRAD has three types of nodes:
- Actuation nodes – Allows external actuators like relays or solenoids
- Sensory nodes – Reports data from sensors (light, temperature, motion)
- Hub nodes – Hosts control panel, records data, provides external data interfaces
Continue reading “Ridiculously Automated Dorm Room”