Hackaday Prize Entry: Worldwide Educational Infrastructure

The future of education is STEM, and for the next generation to be fitter, happier, and more productive, classrooms around the world must start teaching programming, computer engineering, science, maths, and electronics to grade school students. In industrialized countries, this isn’t a problem: they have enough money for iPads, Chromebooks, and a fast Internet connection. For developing economies? That problem is a little harder to solve. Children in these countries go to school, but there are no racks of iPads, no computers, and even electricity isn’t a given. To solve this problem, [Eric] has created a portable classroom for his entry into this year’s Hackaday Prize.

Classrooms don’t need much, but the best education will invariably need computers and the Internet. Simply by the virtue of Wikipedia, a connection to the Internet multiplies the efforts of any teacher, and is perhaps the best investment anyone can make in the education of a child. This was the idea behind the One Laptop Per Child project a decade ago, but since then, ARM boards running Linux have become incredibly cheap, and we’re getting to a point where cheap Internet everywhere is a real possibility.

To build this portable classroom, [Eric] is relying on the Raspberry Pi. Yes, there are cheaper options, but the Pi is good enough. A connection to online resources is required, and for that [Eric] is turning to the Outernet. It’s a system that will broadcast educational material down from orbit, using ground stations made from cheap and portable KU band satellite dishes and cheap receivers.

When it comes to educational resources for very rural communities, the options are limited. With [Eric]’s project, the possibilities for educating students on the basics of living in the modern world become much easier, and makes for a great entry into this year’s Hackaday Prize.

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Hackaday Prize Entry: Industrial Servo Control On The Cheap

[Oscar] wonders why hobby projects ignore all the powerful brushless motors available for far less than the equivalent stepper motors, especially with advanced techniques available to overcome their deficiencies.  He decided it must be because there is simply not a good, cheap, open source motor controller out there to drive them precisely. So, he made one.

Stepper motors are good for what they do, open-loop positioning along a grid, but as far as industrial motors go they’re really not the best technology available. Steppers win on the cost curve for being uncomplicated to manufacture and easy to control, but when it comes to higher-end automation it’s servo control all the way. The motors are more powerful and the closed-loop control can be more precise, but they require more control logic. [Oscar]’s board is designed to fill in this gap and take full advantage of this motor control technology.

The board can do some pretty impressive things for something with a price goal under $50 US dollars. It supports two motors at 24 volts with up to 150 amps peak current. It can take an encoder input for full closed loop control. It supports battery regeneration for braking. You can even augment a more modest power supply to allow for the occasional 1 KW peak movement with  the addition of a lithium battery. You can see the board showing off some of its features in the video after the break.

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Hackaday Prize Entry: Sniffing Defibrillator Data

There’s a lot of implantable medical technology that is effectively a black box. Insulin pumps monitor blood sugar and deliver insulin, but you can’t exactly plug in a USB cable and download the data. Pacemakers and cardiac defibrillators are the same way. For these patients, data is usually transmitted to a base station, then sent over the Internet to help doctors make decisions. The patient never gets to see this data, but with a little work and a software defined radio, a team on Hackaday.io is cracking the code to listen in on these implanted medical devices.

The team behind ICeeData was assembled at a Health Tech Hackathon held in Latvia last April. One of the team members has an implanted defibrillator keeping her ticker in shape, and brought along her implant’s base station. The implant communicates via 402-405MHz radio, a region of the spectrum that is easily accessible by a cheap RTL-SDR TV Tuner dongle.

Right now the plan is to intercept the communications between the implant and the base station, decode the packets, decipher the protocol, and understand what the data means. It’s a classic reverse engineering task that would be the same for any radio protocol, only with this ones, the transmissions are coming from inside a human.


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Hackaday Prize Entry: Open Source Electrospinning Machine

Electrospinning is a fascinating process where a high voltage potential is applied between a conductive emitter nozzle and a collector screen. A polymer solution is then slowly dispensed from the nozzle. The repulsion of negative charges in the solution forces fine fibers emanate from the liquid. Those fibers are then rapidly accelerated towards the collector screen by the electric field while being stretched and thinned down to a few hundred nanometers in diameter. The large surface area of the fine fibers lets them dry during their flight towards the collector screen, where they build up to a fine, fabric-like material. We’ve noticed that electrospinning is hoped to enable fully automated manufacturing of wearable textiles in the future.

[Douglas Miller] already has experience cooking up small batches of microscopic fibers. He’s already made carbon nanotubes in his microwave. The next step is turning those nanotubes into materials and fabrics in a low-cost, open source electrospinning machine, his entry for the Hackaday Prize.

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Hackaday Prize Entry: Internets Of Energy

More and more, the power grid is distributed. Houses have solar panels on their roofs, and where possible, that excess power is sold back to the grid. The current trend is towards smart meters that record consumption for an entire household and relay it back to the power plant every day or so. The future is decentralized, through, and a meter that is smart once a day simply won’t do. A team on Hackaday.io has put together the ultimate in decentralized energy modernization. It’s the InternetS of Energy, and it removes the need for power companies completely.

The team has identified a few key features of the current power grid that don’t make sense in the age of the Internet. The power company doesn’t have extremely granular data, and sending power over long distances is either inefficient or expensive. The solution for this is to have distributed power plants, all connected together into a truly intelligent power grid.

This InternetS of Energy uses open-source energy monitoring systems running the Ethereum client to push power-usage data onto the blockchain. This makes the grid secure and pseudonymous, and if the banking industry is any indication, something like this is the future of economic transactions.

While it may not be the best solution for mature power grids, it is an extremely interesting avenue of research for developing nations. Wherever local resources allow it, electricity can be generated and sent to where it’s needed. It’s exactly what the power grid would be if it were re-designed today from scratch, and an excellent candidate for the 2016 Hackaday Prize.

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After The Prize: SatNOGS Builds Satellites

When Hackaday announced winners of the 2014 Hackaday Prize, a bunch of hackers from Greece picked up the grand prize of $196,418 for their SatNOGS project – a global network of satellite ground stations for amateur Cubesats.

upsat-integration-test-1The design demonstrated an affordable ground station which can be built at low-cost and linked into a public network to leverage the benefits of satellites, even amateur ones. The social implications of this project were far-reaching. Beyond the SatNOGS network itself, this initiative was a template for building other connected device networks that make shared (and open) data a benefit for all. To further the cause, the SatNOGS team set up the Libre Space Foundation, a not-for-profit foundation with a mission to promote, advance and develop Libre (free and open source) technologies and knowledge for space.

Now, the foundation, in collaboration with the University of Patras, is ready to launch UPSat – a 2U, Open Source Greek Cubesat format satellite as part of the QB50 international thermosphere research mission. The design aims to be maximally DIY, designing most subsystems from scratch. While expensive for the first prototype, they hope that documenting the open source hardware and software will help kickstart an ecosystem for space engineering and technologies. As of now, the satellite is fully built and undergoing testing and integration. In the middle of July, it will be delivered to Nanoracks to be carried on a SpaceX Dragon capsule and then launched from the International Space Station.

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Hackaday Prize Entry: Harmonicas, Candy, And Van Halen

Watch enough How It’s Made, and you’ll soon become very enthusiastic about computer vision and compressed air. In factories all around the world, production lines automatically sort the wheat from the chaff by running a product underneath a camera and blowing defective product off the line.

For his Hackaday Prize entry, [Fabien] is attempting this same task. He’s building a machine that will rapidly sort candy with computer vision and precisely controlled jets of air. He’s also planning for the Van Halen reunion and building a CNC harmonica.

Right now, the design has a hopper full of M&Ms dropping through a channel where a camera looks at each individual piece of candy. A Raspberry Pi, camera, and OpenMV detect all the red, yellow, brown, and blue M&Ms, and send that information to a computer controlling a suite of pneumatic valves. When these valves open, candy of different colors is shuffled off into it’s own bin. It’s the perfect device for someone responsible for reading Van Halen’s rider.

In an interesting little side project, [Fabien] needed a way to test the pneumatic valves before building the color sensor and candy chute. He had a harmonica lying around, and built something we’re surprised we’ve never seen before. It’s a CNC harmonica, capable of belting out a few tunes. You can check out that testing video after the break.

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